Solutions Manual

Solutions Manual

This booklet is provided in Glencoe Geometry Answer Key Maker (0-07-860264-5). Also provided are solutions for problems in the Prerequisite Skills, Extra Practice, and Mixed Problem Solving sections.

Copyright © by The McGraw-Hill Companies, Inc. All rights reserved. Printed in the United States of America. Permission is granted to reproduce the material contained herein on the condition that such material be reproduced only for classroom use; be provided to students, teacher, and families without charge; and be used solely in conjunction with Glencoe Geometry. Any other reproduction, for use or sale, is prohibited without prior written permission of the publisher.

Send all inquiries to: Glencoe/McGraw-Hill 8787 Orion Place Columbus, OH 43240-4027

ISBN: 0-07-860204-1

1 2 3 4 5 6 7 8 9 10 009 12 11 10 09 08 07 06 05 04 03

Geometry Solutions Manual

CONTENTS Chapter 1 Points, Lines, Planes, and Angles. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Chapter 2 Reasoning and Proof . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 24 Chapter 3 Parallel and Perpendicular Lines. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 Chapter 4 Congruent Triangles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 Chapter 5 Relationships in Triangles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .120 Chapter 6 Proportions and Similarity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .151 Chapter 7 Right Triangles and Trigonometry. . . . . . . . . . . . . . . . . . . . . . . . . . .. 189 Chapter 8 Quadrilaterals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 238 Chapter 9 Transformations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 289 Chapter 10 Circles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 345 Chapter 11 Areas of Polygons and Circles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 383 Chapter 12 Surface Area . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 411 Chapter 13 Volume………………………………………………………...447 Prerequisite Skills …………………………………………………………477 Extra Practice………………………………………………………………502 Mixed Problem Solving and Proof…………………………………………567

Chapter 1 Points, Lines, Planes, and Angles 2. See students’ work; sample answer: Two lines intersect at a point. 3. Micha; the points must be noncollinear to determine a plane. 4. Sample answers: line p; plane R 5. Sample answer: y

Page 5 Getting Started 1–4.

y

D( 1, 2) B(4, 0) x

O

A(3, 2)

W

C( 4, 4)

x O

X

3 6 3 5. 3 4 8 8 8 1 9 8 18

Z Y

5 37 4 1 1 6. 2 16 5 8 ¬ 16 8 37 82 ¬ 16 16

6.

r

P

11 9 7 ¬ 16 ¬7 16

s Q

14 9 9 7. 7 8 16 ¬ 16 16 5 ¬ 16 23 15 1 7 8. 11 1 2 9 16 ¬ 2 16 18 4 15 1 ¬ 16 16 33 1 ¬ 16 2 16

7. There are six planes: plane ABC, plane AGE, plane CDE, plane BCD, plane FAB, and plane DEF. 8. A, K, B or B, J, C 9. No; A, C, and J lie in plane ABC, but D does not. 10. line 11. point 12. plane

9. 2 17 15 10. 23 (14)¬ 23 14 37 11. [7 (2)]2¬ (7 2)2 (5)2 25 12. 92 132¬ 81 169 250 13. P¬ 4s 4(5) 20 The perimeter is 20 in. 14. P¬ 2 2w ¬ 2(6) 2 21 2

Pages 9–11

n R Sample answer: PR Yes, it intersects both lines are extended. 19. (D, 9) 21. B

¬ 12 5 17 The perimeter is 17 ft. 15. P¬ 2 2w 2(4.8) 2(7.5) 9.6 15 24.6 The perimeter is 24.6 m.

1-1

Practice and Apply

13. 15. 17. 18.

W

14. F 16. W m and n when all three 20. Charlotte

Q

A 22. R W T 23. Sample answer:

Points, Lines, and Planes

y

Page 8 Geometry Activity

R

S Z

1. no 2. no 3. On CD; see students’ work. 4. See students’ work.

x

O

Q

Page 9 Check for Understanding 1. point, line, plane

1

Chapter 1

24. Sample answer:

36. Sample answer: points E, A, and B are coplanar, but points E, A, B, and C are not. 37. AC 38. point 39. lines 40. plane 41. plane 42. two planes intersecting in a line 43. point 44. intersecting lines 45. point 46. line 47.

y

R

C P

D S

x

O

25.

a b c

26.

48.

a b

F

V c 27.

s C

49. See students’ work. 50. Sample answer: the image is rotated so that the front or back plane is not angled. 51. Sample answer:

r

D

M

s

28.

A B

C 52. See picture. 53. vertical 54. Sample answer: the paths flown by airplanes flying in formation 55. Sample answer: Chairs wobble because all four legs do not touch the floor at the same time. Answers should include the following. • The ends of the legs represent points. If all points lie in the same plane, the chair will not wobble. • Because it only takes three points to determine a plane, a chair with three legs will never wobble. 56. C; Three lines intersect in a maximum of three points. The fourth line can cross the other three lines only one time each, adding three points to the figure. For example,

29. points that seem collinear; sample answer: (0, 2), (1, 3), (2, 4), (3, 5) y

O

x

30. There are five planes: plane ABC, plane BCE, plane ABE, plane ADE, and plane CDE. 31. 1; There is exactly one plane through any three noncollinear points. 32. E, F, C 33. Because A and B determine a line, add point G . anywhere on AB 34. E, F 35. A, B, C, D or E, F, C, B

Chapter 1

2

57. B; 2 x 2 x 2x22x2 x x x x x x 2x 0 Thus, x must be 0. 58. y

1-2 Page 16

Linear Measure and Precision Check for Understanding

1. Align the 0 point on the ruler with the leftmost endpoint of the segment. Align the edge of the ruler along the segment. Note where the rightmost endpoint falls on the scale and read the closest eighth of an inch measurement. 2. Sample answers: rectangle, square, equilateral triangle 3. Each inch on the ruler is divided into eighths. Point Q is closer to the 16 Q is 8 -inch mark. Thus, P or 13 inches long. about 16 8 4 4. The long marks on the ruler are centimeters, and the shorter marks are millimeters. There are 10 millimeters for each centimeter. Thus, the bee is 13 millimeters or 1.3 centimeters long. 5. The measurement is precise to within 0.5 meter. So, a measurement of 14 meters could be 13.5 to 14.5 meters. 1 6. The measuring tool is divided into 4-inch increments. Thus, the measurement is precise 1 1 to within 1 2 4 or 8 inch. Therefore, the 1 1 measurement could be between 31 4 8 38 1 3 inches and 31 4 8 3 8 inches.

x

O

a line 59.

y

x

O

part of the coordinate plane above the line y 2x 1 4 1 3 60. 1 2 8 , so 2 in. 8 in. 4 4 1 61. 1 4 16 , so 16 in. 4 in.

7. EG EF FG EG 2.4 1.3 EG 3.7 So, E G is 3.7 centimeters long. 8. XY YZ¬ XZ XY 15 8 ¬ 3

8 4 6 62. 4 5 10 , so 5 in. 10 in. 63. 10 mm 1 cm 64. 2.5 cm 25 mm, so 2.5 cm 28 mm 65. 0.025 cm 0.25 mm, so 0.025 cm 25 mm

Page 12

5 5 XY 15 8 1 8 ¬ 3 1 8 3 XY¬ 18 3 So, X Y is 18 inches long.

Reading Mathematics

9.

1. Points P, Q, and R lie on . Point T is not collinear with P, Q, and R. 2. Planes F, G, and H intersect at line j. 3. The intersection of planes W, X, Y, and Z is point P. 4.

5x

3x

15 N

L

M

NL 5x¬ 15 5 x 15 5 ¬ 5

A

x¬ 3 LM 3x LM 3(3) LM 9

B C 10.

30 6x 5

N

2x 3

L

M

NM¬ NL LM 30¬ 6x 5 2x 3 30¬ 8x 2 30 2¬ 8x 2 2 32¬ 8x 3 2 8 x 8 ¬ 8

3

Chapter 1

XZ 5 4

4¬ x LM 2x 3 LM 2(4) 3 8 3 LM 11 11. B C C D because they both have length 10 inches. E B E D because they both have length 8 inches. A B D A because they both have length 14.4 inches.

Pages 17–19

1 So, X Z is 5 4 or 1 4 inches long.

5 5 5 9 1 6 ¬ 1 6 QR 16 4 36 5 16 16 ¬ QR 31 16 ¬ QR 31 15 So, Q R is 16 or 1 16 inches long.

RT¬ RS ST 4.0¬ 1.2 ST 4.0 1.2¬ 1.2 ST 1.2 2.8¬ ST So, S T is 2.8 centimeters long. 26. WY WX XY 4.8 WX WX W X is congruent to X Y . 4.8 2WX

Practice and Apply

25.

12. Each inch on the ruler is divided into sixteenths. 5 Point B is closer to the 1 -inch mark. Thus, A B 16 5 is about 1 inches long. 16 13. The long marks on the ruler are centimeters, and the shorter marks are millimeters. Point D is closer to the 45-millimeter mark. Thus, C D is about 45 millimeters or 4.5 centimeters long. 14. The long marks on the ruler are centimeters, and the shorter marks are millimeters. The right end of the key is closer to the 33-millimeter mark. Thus, the key is about 33 millimeters or 3.3 centimeters long.

4.8 2W X 2 2

2.4 WX So, W X is 2.4 centimeters long. 27. AD¬ AB BC CD 33 B is congruent to B C 4 ¬ BC BC BC A and C D is congruent to B C . 33 4 ¬ 3BC

15. Each inch on the ruler is divided into sixteenths. The right tip of the paperclip is closer to the 4 4 1 -inch mark. Thus, the paperclip is about 1 16 16 1 or 14 inches long. 16. The measurement is precise to within 1 2 inch. So, 1 a measurement of 80 inches could be 79 1 2 to 80 2 inches. 17. The measurement is precise to within 0.5 millimeter. So, a measurement of 22 millimeters could be 21.5 to 22.5 millimeters.

1 5 1 1 3 4 3 (3BC) 15 12 ¬ BC 3 1 So, B C is 1 1 2 or 14 inches long.

28.

7a

12a

28 R

S

T

RS 7a¬ 28

18. The measuring tool is divided into 1 2 -inch increments. Thus, the measurement is precise to 1 1 within 1 2 2 or 4 inch. Therefore, the 1 1 measurement could be between 161 2 4 16 4 1 1 3 inches and 162 4 164 inches.

7a 28 ¬ 7 7

a¬ 4 ST 12a ST 12(4) ST 48

19. The measurement is precise to within 0.5 centimeter. So, a measurement of 308 centimeters could be between 307.5 and 308.5 centimeters. 20. The measurement is precise to within 0.005 meter or 5 millimeters. So, a measurement of 3.75 meters 3750 millimeters could be between 3745 and 3755 millimeters.

29.

34 2x

12 R

S

RT RS ST 34 12 2x 34 12 12 2x 12 22 2x

21. The measuring tool is divided into 1 4 -foot

increments. Thus, the measurement is precise to 1 1 within 1 2 4 or 8 foot. Therefore, the measurement could be between

2 2 2 x 2 2

1 1 1 1 3 31 4 8 3 8 feet and 3 4 8 3 8 feet.

11 x ST 2x ST 2(11) ST 22

22. AC AB BC AC 16.7 12.8 29.5 So, A C is 29.5 millimeters long. 23. XZ XY YZ 3 2 3 XZ 1 2 4 4 4

Chapter 1

PR¬ PQ QR 5 21 4 ¬ 16 QR

24.

4

T

30.

34. 35. 36. 37. 38. 39.

25 2x R

3x S

T

RT¬ RS ST 25¬ 2x 3x 25¬ 5x 2 5 x 5 5 ¬ 5 5¬ x ST¬ 3x ST¬ 3(5) ST¬ 15 31.

40. 41. 42.

43.

5x 10 2x

16

R

S

44. T

RT¬ RS ST 5x 10¬ 16 2x 5x 10 10¬ 16 2x 10 5x¬ 6 2x 5x 2x¬ 6 2x 2x 3x¬ 6 3 x 6 3 3 x¬ 2 ST¬ 2x ST¬ 2(2) ST¬ 4 32.

45.

46.

47.

21

48. 3y 1

2y

R

S

F 3(AB)

50a. 2 50b. 5 50c. 7 51. Sample answer: Units of measure are used to differentiate between size and distance, as well as for accuracy. Answers should include the following. • When a measurement is stated, you do not know the precision of the instrument used to make the measure. Therefore, the actual measure could be greater or less than that stated. • You can assume equal measures when segments are shown to be congruent.

2y 1

S

2(CD) E

5y

R

F

4(CD)

49.

T

4y 1

E EF

RT¬ RS ST 21¬ 3y 1 2y 21¬ 5y 1 21 1¬ 5y 1 1 20¬ 5y 2 5 y 0 5 ¬ 5 4¬ y ST¬ 2y ST¬ 2(4) ST¬ 8 33.

yes; AB CD 3 cm no; EF 6 ft and FG 8 ft no; NP 1.75 in. and LM 0.75 in. yes; WX XY 6 m not from the information given yes; TR¬ 3(a b) 3c 3a 3b 3c SU¬ 3a 3(b c) 3a 3b 3c The width of a music CD is 12 centimeters. F C D G , A B H I, C E E D E F E G 144 cm3; 343 mL could be actually as much as 343.5 mL and 200 mL as little as 199.5 mL; 343.5 199.5 144. The lengths of the bars are given in tenths of millions, and 0.1 million 100,000. So the graph is precise to within 50,000 visitors. 50,000 0.05 million, so a measurement of 98.5 million could be 98.45 million to 98.55 million visitors. No; the number of visitors to Washington state parks could be as low as 46.35 million or as high as 46.45 million. The visitors to Illinois state parks could be as low as 44.45 million or as high as 44.55 million visitors. The difference in visitors could be as high as 2.0 million. 12.5 cm; Each measurement is accurate within 0.5 cm, so the least perimeter is 2.5 cm 4.5 cm 5.5 cm. 15.5 cm; Each measurement is accurate within 0.5 cm, so the greatest perimeter is 3.5 cm 5.5 cm 6.5 cm.

T

RT¬ RS ST 5y¬ 4y 1 2y 1 5y¬ 6y 2 5y 2¬ 6y 2 2 5y 2¬ 6y 5y 2 5y¬ 6y 5y 2¬ y ST¬ 2y 1 ST¬ 2(2) 1 ST¬ 3

allowab le error 0.5 ft 52. measure 27 ft 0.019 or 1.9% allowab le error 0.25 in. 53. measure 14.5 in. 0.017 or 1.7% allowab le error 0.05 cm 54. measure 42.3 cm 0.001 or 0.1% allowab le error 0.05 km 55. measure 63.7 km 0.0008 or 0.08% 56. B; 5(12 in.) 60 in. or 5 ft

5

Chapter 1

57. D; forty percent are jazz tapes so sixty percent are blues tapes; 0.60(80) 48.

Page 19

1-3

Page 22 Geometry Activity: Midpoint of a Segment

Maintain Your Skills

58. 59. 60. 61.

B, G, E Sample answer: planes ABC and BCD C There are five planes shown: plane ABC, plane BCDE, plane DEF, plane ACDF, and plane ABEF. 62. 2a 2b¬ 2(3) 2(8) ¬ 6 16 22 63. ac bc¬ (3)(2) (8)(2) 6 16 22 2 a c 3 1 64. 2 2 2

1.

1. PR 4.

4.5

3. R

x

y

T

Y

Z

TS RS TR TS 6 4.5 TS 10.5 5.

A

AC ¬ (2 5 )2 (5 5)2 2 AC ¬(3) 02 AC ¬ 9 AC ¬3 C A ¬C B , so both are 3 units long.

3. PR

2. T

S

C

(2, 5) 2 2. d ¬(x y2 y1)2 2 x 1) (

Practice Quiz 1 6

y

B

O

2 65. (c ) a¬ (2 ) 32 (1) 2 1 1

Page 19

Distance and Midpoints

X

11.75 O

x

3.4 S

R

(1, 5) 2 2 d ¬(x 2 x 1) (y 2 y 1) 2 XZ ¬ [1 (4)] (5 3)2 2 2 XZ ¬3 2 XZ ¬ 13 Z X ¬Z Y , so both are 13 units or about 3.6 units long. 5. Sample answer: The x-coordinate of the midpoint is one half the sum of the x-coordinates of the endpoints. The y-coordinate of the midpoint is one half the sum of the y-coordinates of the endpoints.

T

TS¬ RS TR 11.75¬ RS 3.4 11.75 3.4¬ RS 3.4 3.4 8.35¬ RS

4.

Page 20 Geometry Activity: Probability and Segment Measure 1. WZ WX XY YZ WZ 2 1 3 6 XY P(J lies in XY) W Z 1 6

Page 25 Check for Understanding

2. WZ WX XY YZ WZ 2 1 3 6

1. Sample answers: (1) Use one of the Midpoint Formulas if you know the coordinates of the endpoints. (2) Draw a segment and fold the paper so that the endpoints match to locate the middle of the segment. (3) Use a compass and straightedge to construct the bisector of the segment.

YZ P(R lies in YZ) W Z 1 3 6 2

3. WY WX XY WY 2 1 WY 3 XY P(S lies in XY) W Y 1 3 4. 1; X Y contains all points that lie on both W Y and X Z . 5. 0; if point U lies on W X , it cannot lie on Y Z .

Chapter 1

6

2. Sample answer:

4 2x 7 2

P

M

4 2x 6 2x 2 2

B

6 2x 2

8

14 4 2x 10 2x 5x

7 mm 7 mm

A

12. B; M(7, 8) M ,

16 6 2x 10 2x 5x

Q

Pages 25–27

5.

Practice and Apply

13. DE ¬|2 4| ¬|2| or 2 15. AB ¬|4 (1)| ¬|3| or 3 17. AF ¬|4 7| ¬|11| or 11

3. AB |2 10| |8| or 8 4. CD |3 4| |7| or 7 y

X

12

19.

y 8

8

Y 4

4

x 8

8

(6)2

A

4

X

8

+

(8)2

(AB)2 (AX)2 (BX)2 (AB)2 (8)2 (6)2 (AB)2 100 AB 10

(XY)2 36 + 64 (XY)2 100 XY 10

20.

2 2 d ¬ (x2 x y2 y 1) ( 1)

6.

4

4

(XY)2 (XW)2 + (YW)2 (XY)2

B

4

W x

8

14. CF ¬|0 7| ¬|7| or 7 16. AC ¬|4 0| ¬|4| or 4 18. BE ¬|1 4| ¬|5| or 5

y

DE ¬ (8 2 )2 (6 0)2 ¬ 62 62 DE ¬ 36 36 DE ¬ 72 DE ¬8.49

D

(2) 10 7. M 2

C

12 2

X x 0

6

(CD)2 (3)2 (4)2 (CD)2 25 CD 5 (CD)2

3 6 8. M 2

3 2 or 1.5 x1 x2 y1 y2 4 (1) 3 5 9. , , 2 2 2 2 8 5 2, 2 or (2.5, 4) x1 x2 y1 y2 2 (2) 8 2 10. , , 2 2 2 2

(CX)2

21. 12

y

F

8

(0, 5)

4

x1 (3) y1 6 11. B(0, 5.5) B , 2 2 x1 (3) y1 6 0 5.5 2 2

(DX)2

x 8

E

4

0 x1 (3) 11 y1 6 3 x1 5 y1 The coordinates of A are (3, 5)

X

8

(EF)2 (EX)2 (FX)2 (EF)2 (5)2 (12)2 (EF)2 169 EF 13

7

Chapter 1

22.

y

8

AB ¬ [5 (4)]2 [1 (3)] 2 2 2 AB ¬(1) 4 1 16 AB ¬ 17 Because the figure is a square, the four sides are congruent. So the perimeter of the square is 4 17 16.5 units.

4

x 4

8

0

G8

8

4

X

6 0 31. M ¬ 2

¬ (x2 x1)2 (y2 y1)2 2 (9 ¬ (7 3) 5)2 42 42

d

27.

x1 x2 y1 y2 9 17 5 4 38. , ¬ 2, 2

2

2

2 6 9 ¬ 2 , 2

¬(13, 4.5)

x1 x2 y1 y2 11 (9) 4 (2) 39. , ¬ 2, 2 2 2 20 6 ¬ 2, 2

32 42

¬(10, 3)

2 2 d ¬ (x2 x y2 y 1) ( 1) 2 NP ¬ [3 (2)] [4 (2)]2 2 2 NP ¬5 6 25 36 NP ¬ 61 NP ¬7.8

28.

¬2 2

¬(10, 3)

UV UV ¬ 9 16 25 UV ¬5

3 5 36. M ¬ 2

¬1

ST ¬ [6 ( 3)]2 (5 2)2 2 2 ST ¬9 3 81 9 ST ¬ 90 ST ¬9.5 26.

1 ¬ 2 or 0.5

¬1

2 2 d ¬ (x2 x y2 y 1) ( 1)

¬ (x2 x1)2 (y2 y1)2 2 (7 ¬ (5 2) 3)2

3 2

34. M ¬2

x1 x2 y1 y2 8 12 4 2 37. , ¬ 2, 2 2 2 2 0 6 ¬ 2 , 2

LM LM ¬ 16 16 32 LM ¬5.7 25.

¬5

5 0 33. M ¬ 2 ¬5 2 or 2.5 6 8 35. M ¬ 2 2 ¬2

2 2 d ¬ (x2 x y2 y 1) ( 1)

d

8

1 0 ¬ 2

¬3

JK ¬ (12 0)2 (9 0 )2 122 92 JK ¬225 15 24.

2 32. M ¬ 2

6 ¬ 2

(GH)2 (GX)2 (HX)2 (GH)2 (8)2 (15)2 (GH)2 289 GH 17 23.

2 2 d ¬ (x2 x 1) (y 2 y 1)

30.

H

x1 x2 y1 y2 4 8 2 (6) 40. , ¬ 2, 2

2

4 12 ¬ 2 , 2

¬(6, 2)

2 2 d ¬ (x2 x 1) (y 2 y 1)

x1 x2 y1 y2 3.4 7.8 2.1 3.6 41. , ¬ 2, 2 2 2 11 .2 5.7 ¬ 2 , 2

QR ¬[1 ( 5)]2 (5 3)2 2 2 QR ¬ 6 2 36 4 QR ¬ 40 QR ¬6.3 2 2 29. d ¬ (x2 x y2 y 1) ( 1) 2 XY ¬ [2 ( 2)] [5 (1)]2 2 2 XY ¬4 6 16 3 6 XY ¬ 52 2 (3 YZ ¬ (4 2) 5)2 2 2 YZ ¬ 2 ( 2) 44 YZ ¬ 8 XZ ¬ [4 ( 2)]2 [3 (1)]2 2 42 XZ ¬6 36 1 6 XZ ¬ 52 XY YZ XZ 52 8 52 17.3 units

Chapter 1

2

¬(5.6, 2.85)

x x 2

y y 2

1.4 2.6

3.2 (5.4) 1 2 1 2 42. , ¬ 2, 2

1.2 2 .2 ¬ 2 , 2 ¬(0.6, 1.1)

x1 (4) y1 3 43. S(1, 5) , 2 2 x1 (4) y1 3 1 ¬ 5 ¬ 2 2

2 ¬x1 (4) 10 ¬y1 3 2 ¬x1 7 ¬y1 The coordinates of R are (2, 7).

x 2 y 8 2 2

1 1 44. S(2, 2) ,

x1 2 2 ¬ 2

y 8

1 2 ¬ 2 4 ¬x1 2 4 ¬y1 8 6 ¬x1 4 ¬y1 The coordinates of R are (6, 4).

8

2 x2

3

5 y

52. The new coordinates are A(3, 9), B(18, 30), and C(33, 54). 2 2 d ¬ (x2 x y2 y 1) ( 1) 2 AB ¬ (18 3) (30 9)2 2 2 AB ¬ 15 21 225 441 AB ¬ 666 BC ¬ (33 18)2 (54 30)2 2 2 BC ¬ 15 24 225 576 BC ¬ 801 AC ¬ (33 3)2 (54 9)2 AC ¬ 302 452 900 2025 AC ¬ 2925 The perimeter of ABC is 666 801 2925, which is approximately 108.2 units. 53. Sample answer: The perimeter increases by the same factor.

45. S 5 , 2 3, 3 2 2 2 x2 3 5 ¬ 3 2 10 ¬2 x2 3 3 8 ¬x2 3

5 y 2

3 ¬2 6 ¬5 y2

11 ¬y2

The coordinates of T are 8 3 , 11 . x1 31.8 y1 106.4 46. M(31.1, 99.3) , 2 2 x1 31.8 y1 106.4 31.1 ¬ 99.3 ¬ 2 2

62.2 ¬x1 31.8

198.6 ¬y1 106.4

30.4 ¬x1

92.2 ¬y1

The other endpoint is at (30.4°, 92.2°). 47. LaFayette, LA is near (30.4°, 92.2°). 48. Sample answer: SQRT((A2 C2) 2 (B2 D2) 2) 49a. (54 113)2 (12 0 215) 2 111.8 2 49b. (68 175) (15 3 33 6)2 212.0 2 49c. (421 502) (45 4 798) 2 353.4 49d. (837 612)2 (98 0 62 5)2 420.3 2 49e. (1967 1998) (3 24) 2 37.4 2 49f. (4173 .5 2 080.6 ) (3 4.9 22.4) 2 2092.9 50.

x1 x2 y1 y2 26 66 54a. F , F 2, 2

2

2

8 1 2 F2, 2 or F(4, 6)

x1 x2 y1 y2 66 62 E , E 2, 2

2

2

1 2 8 E2, 2 or E(6, 4)

54b. G(4, 4); it has the same x-coordinate as F and the same y-coordinate as E. 54c. D G G B ; use the Distance Formula to show DG GB. 2 2 d ¬(x 2 x 1) (y 2 y 1)

2 2 d ¬(x 2 x 1) (y 2 y 1)

2 (1 AB ¬ (6 1) 0 3)2 2 2 AB ¬5 7 25 49 AB ¬ 74 BC ¬ (11 6)2 (18 10)2 2 2 BC ¬5 8 25 6 4 BC ¬ 89 2 AC ¬ (11 1) (18 3)2 2 2 AC ¬10 15 100 225 AC ¬ 325 The perimeter of ABC is 74 89 325 , which is approximately 36.1 units. 51. The new coordinates are A(2, 6), B(12, 20), C(22, 36). 2 2 d ¬(x 2 x 1) (y 2 y 1)

2 (4 DG ¬ (4 2) 2)2 2 2 DG ¬ 2 2 44 DG ¬ 8 GB ¬ (6 4 )2 (6 4)2 2 2 GB ¬ 2 2 44 GB ¬ 8 Thus, DG GB.

1 55. 1 4 (x2 x1) 4 [5 (3)] 1 4 (8) 2 1(y2 y1) 1[12 (8)] 4 4 1 4 (20) 5

AB ¬ (12 2)2 (20 6)2 AB ¬ 102 142 100 196 AB ¬ 296 BC ¬ (22 12)2 (36 20)2 2 2 BC ¬ 10 16 100 256 BC ¬ 356 AC ¬ (22 2)2 (36 6)2 2 2 AC ¬ 20 30 400 900 AC ¬ 1300 The perimeter of ABC is 296 356 1300, which is approximately 72.1 units.

(3 2, 8 5) (1, 3) Verify that the coordinates of X are (1, 3): WX [1 (3)]2 [ 3 (8)] 2 2 2 WX 2 5 WX 4 25 WX 29 WZ [5 ( 3)]2 [12 (8)] 2 2 2 WZ 8 2 0 WZ 64 4 00 WZ 464 29 5.385 464 21.540 1 5.385 1 4 (21.540), so WX 4 WZ.

9

Chapter 1

66. 12m 7 ¬3m 52 12m ¬3m 45 9m ¬45 m ¬5 67. 8x 7 ¬5x 20 8x ¬5x 13 3x ¬13 1 3 x ¬ 3 68. 13n 18 ¬5n 32 13n ¬5n 50 8n ¬50 5 0 n ¬ 8 or 6.25

56. Sample answer: You can copy the segment onto a coordinate plane and then use either the Pythagorean Theorem or the Distance Formula to find its length. Answers should include the following. • To use the Pythagorean Theorem, draw a vertical segment from one endpoint and a horizontal segment from the other endpoint to form a triangle. Use the measures of these segments as a and b in the formula a2 b2 c2. Then solve for c. To use the Distance Formula, assign the coordinates of the endpoints of the segment as (x1, y1) and (x2, y2). 2 2 y2 y Then use them in d (x 2 x 1) ( 1) to find the length of the segment. • 61 7.8 units

Page 28 Geometry Activity: Modeling the Pythagorean Theorem

2 2 57. B; d ¬(x 2 x 1) (y 2 y 1)

1. 2. 3. 4.

25, 144, 169 25 144 169 a2, b2, c2 The formula for the Pythagorean Theorem can be expressed as a2 b2 c2. 5. All of these fit the a2 b2 c2 pattern. 6. The number of grid squares is 52 52, which is 50 grid squares.

d ¬ (2 6)2 (4 11)2 2 2 d ¬(8) (15) d ¬ 64 2 25 d ¬ 289 d ¬17 58. A

Page 27


59. WY WX XY 1 WY 13 4 22

1-4

WY 41 4 W Y is 41 4 in. long. 60. AC AB BC 8.5 3 BC 5.5 BC BC is 5.5 cm long. 61. Sample answer:

Page 32 Geometry Activity: Bisect an Angle 1. They are congruent. 2. See students’ work. 3. A segment bisector separates a segment into two congruent segments; an angle bisector separates an angle into two congruent angles. A C

B


D

1. Yes; they all have the same measure. 2. Sample answer:

m

62.

A

S

n

2k ¬5k 30 3k ¬30 k ¬10 64. 14x 31 ¬12x 8 14x ¬12x 39 2x ¬39 39 x ¬ 2 or 19.5 63.

3. 4. 5. 6. 7. 8.

65. 180 8t ¬90 2t 90 8t ¬2t 90 ¬10t 9 ¬t

Chapter 1

Angle Measure

10

T

R

m QPR 60 P Q m QPT 90 mA mZ m QPS 120 C BA, BC CDB, 1 135°; 135 90 and 135 180 so WXY is obtuse. 45°; 45 90 so WXZ is acute.

9. QT bisects RQS, so RQT SQT. mRQT mSQT 6x 5 ¬7x 2 6x 7 ¬7x 7 ¬x mRQT 6x 5 6(7) 5 42 5 or 47 10. QT bisects RQS, so RQT TQS and mRQS 2 mRQT. 22a 11 ¬2(12a 8) 22a 11 ¬24a 16 22a 5 ¬24a 5 ¬2a 5 ¬a 2

35. YT bisects XYW, so 1 2. m1 ¬m2 5x 10 ¬8x 23 5x 33 ¬8x 33 ¬3x 11 ¬x m2 ¬8x 23 ¬8(11) 23 ¬88 23 ¬65 36. YT bisects XYW, so mXYW 2 m1. 6y 24 ¬2y 24 ¬4y 6 ¬y 37. YU bisects WYZ, so mWYZ 2 mZYU. 82 ¬2(4r 25) 82 ¬8r 50 32 ¬8r 4 ¬r bisects ZYW, so ZYU UYW, and 38. YU mZYU mUYW. and YZ are opposite rays, so YX mWYX mUYW mZYU ¬180. 2(12b 7) 9b 1 9b 1 ¬180 24b 14 18b 2 ¬180 42b 12 ¬180 42b ¬168 b ¬4 mUYW mZYU 9b 1 9(4) 1 36 1 or 35 39. YU bisects ZYW, so mZYU 1 2 mZYW.

mTQS m RQT 12a 8 12 5 2 8 30 8 or 22 11. 1, right; 2, acute; 3, obtuse

Pages 34–35 Practice and Apply 12. 15. 18. 21. 22. 23. 24. 26. 27.

E 13. B 14. A A 16. D A , DB 17. A B , AD ED, EG 19. AD, AE 20. ABC, CBA FEA, 4 2, DBA, EBA, ABE, FBA, ABF AED, DEA, AEB, BEA, AEC, CEA D, H 25. 2 Sample answer: 4, 3 bisects EAB so 5 6. AD

mZYU ¬1 2 mZYW

1 2 1 ¬(60) 2

m5 ¬mEAB

28. 29. 30. 31. 32. 33. 34.

13a 7 ¬1 2 (90) 13a 7 ¬45 13a ¬52 a ¬4 40. The angle at which the dogs must turn to get the scent of the article they wish to find is an acute angle. 41. Sample answer: Acute can mean something that is sharp or having a very fine tip like a pen, a knife, or a needle. Obtuse means not pointed or blunt, so something that is obtuse would be wide.

¬30 m6 ¬m5 ¬30 BFD is marked with a right angle symbol, so mBFD 90; BFD is a right angle. 60°; 60 90, so AFB is acute. 30°; 30 90, so DFE is acute. 90°; EFC is a right angle. 150°; 150 90 and 150 180, so AFD is obtuse. 120°; 120 90 and 120 180, so EFB is obtuse. YU bisects ZYW, so ZYU UYW. mZYU ¬mUYW 8p 10 ¬10p 20 8p 10 ¬10p 10 ¬2p 5 ¬p mZYU ¬8p 10 8(5) ¬10 40 ¬10 or 30

36 0 42. m1 6 60 36 0 m2 12 30 36 0 m3 4 90 36 0 m4 6 60 36 0 m5 3 120 36 0 m6 6 60

11

Chapter 1

43. m(angle of reflection) ¬1 2 mIBR 1 ¬2(62) ¬31 BN is at a right angle to the barrier. So mIBA 90 31 or 59. 44. You can only compare the measures of the angles. The arcs indicate both measures are the same regardless of the length of the rays. 45. 1, 3, 6, 10, 15 46. 3 rays: (3 2) 2 3 angles; 4 rays: (4 3) 2 6 angles; 5 rays: (5 4) 2 10 angles; 6 rays: (6 5) 2 15 angles 47. 7 rays: (7 6) 2 ¬21 angles 10 rays: (10 9) 2 ¬45 angles

54.

EF ¬ [5 (3)]2 [8 (2)] 2 EF ¬ 82 10 2 64 100 EF ¬164 EF ¬12.8 x x

55. WX WR RX

5 1 WX 3 1 2 6 4 8 2 WX 9 1 2 or 9 3 W X is 92 3 ft long.

56. XZ ¬XY YZ 15.1 ¬3.7 YZ 11.4 ¬YZ Y Z is 11.4 mm long. 57. 6x 5 2x 7 P

58.

Page 36 Maintain Your Skills 2 52. d ¬(x )2 (y 2 x1 2 y 1)

59. 61.

2 (7 AB ¬ (5 2) 3)2 2 2 AB ¬ 3 4 AB ¬ 9 16 25 AB ¬5

y y

2 2 25 37 ¬2, 2 7 10 ¬, or (3.5, 5) 2 2

62.

1 2 1 2 M ¬ ,

53.

63.

2 2 d ¬(x 2 x 1) (y 2 y 1) 2 CD ¬ [6 (2)] (4 0)2

64.

CD ¬ 64 16 CD ¬80 CD ¬8.9 82

x x

42

y y

2 2 2 6 0 4 ¬, 2 2 4 4 ¬, or (2, 2) 2 2

1 2 1 2 M ¬ ,

65.

66.

Chapter 1

y y

2 2 3 5 2 8 ¬2, 2 2 6 ¬2, 2 or (1, 3)

1 2 1 2 M ¬ ,

n(n 1) 48. a 2, for a number of angles and n number of rays 1 49. Sample answer: A degree is of a circle. 360 Answers should include the following. • Place one side of the angle to coincide with 0 on the protractor and the vertex of the angle at the center point of the protractor. Observe the point at which the other side of the angle intersects the scale of the protractor. • See students’ work. 50. D 51. C; 5n 4 ¬7(n 1) 2n 5n 4 ¬7n 7 2n 5n 4 ¬5n 7 4 ¬7

x x

2 2 d ¬(x 2 x 1) (y 2 y 1)

12

Q

R

PQ ¬QR 6x 5 ¬2x 7 6x ¬2x 12 4x ¬12 x ¬3 PQ ¬6x 5 PQ ¬6(3) 5 PQ ¬18 5 or 13 Five planes are shown: plane FJK, plane HJK, plane GHK, plane FGK, and plane FGH. F, L, J 60. G or L 14x (6x 10) ¬90 20x 10 ¬90 20x ¬100 x ¬5 2k 30 ¬180 2k ¬150 k ¬75 180 5y ¬90 7y 90 5y ¬7y 90 ¬2y 45 ¬y 1 90 4t ¬4 (180 t) 4(90 4t) ¬180 t 360 16t ¬180 t 180 16t ¬t 180 ¬15t 12 ¬t (6m 8) (3m 10) ¬90 9m 18 ¬90 9m ¬72 m ¬8 (7n 9) (5n 45) ¬180 12n 36 ¬180 12n ¬144 n ¬12

Page 36 Practice Quiz 2 x x

1-5

y y

2 2 3 (4) 1 3 ¬, 2 2 1 2 ¬, or 1, 1 2 2 2

1 2 1 2 1. M ¬ ,

Page 38 Geometry Activity: Angle Relationships 1. BCE DCA 2. DCB ACE 3. See students’ work. 4. ACD and ECB, DCB and ACE; measures for each pair of vertical angles should be the same. 5. ACD and DCB, DCB and BCE, BCE and ECA, ECA and ACD; measures for each linear pair should add to 180. 6. Sample answers: The measures of vertical angles are equal or vertical angles are congruent. The sum of the measures of a linear pair is 180 or angles that form a linear pair are supplementary.

2 2 d ¬ (x2 x y2 y 1) ( 1)

AB ¬ (4 3)2 [3 (1)] 2 2 AB ¬(7) 42 49 16

AB ¬65 AB ¬8.1 x x

y y

2 2 6 2 4 (8) ¬, 2 2 8 4 ¬, or (4, 2) 2 2

1 2 1 2 2. M ¬ ,

Page 41

2 2 d ¬(x 2 x 1) (y 2 y 1)

Check for Understanding

1.

CD ¬ (2 6 )2 (8 4)2 CD ¬ (4)2 (12) 2 16 144

70

CD ¬160

110

2. Sample answer: When two angles form a linear pair, then their noncommon sides form a straight angle, which measures 180. When the sum of the measures of two angles is 180, then the angles are supplementary. 3. Sample answer: The noncommon sides of a linear pair of angles form a straight line. 4. Sample answer: ABF and CBD are vertical angles. They each have measures less than 90°, so they are acute. 5. Sample answer: ABC and CBE are adjacent angles. They each have measures greater than 90°, so they are obtuse. 6. Explore: The problem involves three angles: an angle, its supplement, and its complement. Plan: Let A be the given angle, B its supplement and C the complement. Then mA mB 180 or mB 180 mA, and mA mC 90 or mC 90 mA. The problem states that mB 3 mC 60, so substitute for mB and mC and solve for mA. Solve: mB ¬3 mC 60 180 mA ¬3(90 mA) 60 180 mA ¬270 3 mA 60 180 2 mA ¬210 2 mA ¬30 mA ¬15 Examine: Check to see if the answer satisfies the problem. The measure of the complement of an angle with a measure of 15° is 75°. The measure of the supplement of the original angle is 165°. 3 75 60 ¬165 165 ¬165 The answer checks.

CD ¬12.6

x x

Angle Relationships

y y

2 2 10 (10) 20 (20) ¬, 2 2

1 2 1 2 3. M ¬ ,

¬(0, 0) 2 2 d ¬ (x2 x y2 y 1) ( 1)

EF ¬(10 10)2 ( 20 2 0)2 EF ¬(20) 2 ( 40)2 EF ¬ 400 1600 EF ¬2000 EF ¬44.7 4. mRXT ¬mSXT mRXS 111 ¬3a 4 2a 5 111 ¬5a 1 110 ¬5a 22 ¬a mRXS 2a 5 2(22) 5 44 5 or 49 5. mQXS ¬mQXR mRXS 4a 1 ¬a 10 91 4a 1 ¬a 101 4a ¬a 102 3a ¬102 a ¬34 mQXS 4a 1 4(34) 1 136 1 or 135

13

Chapter 1

7. Lines p and q are perpendicular if angles 1 and 2 are both right angles. Then m1 m2 90. So 8y 70 90 3x 18 90 3x 72 8y 160 x 24 y 20 8. No; while SRT appears to be a right angle, no information verifies this. 9. Yes; they share a common side and vertex, so they are adjacent. Since P R falls between P Q and P S , mQPR 90, so the two angles cannot be complementary or supplementary. 10. m4 60 and 2 and 4 are vertical angles, so m2 60. 1 and 4 are supplementary angles. m1 m4 ¬180 m1 60 ¬180 m1 ¬120 1 and 3 are vertical angles so m3 120.

18.

Pages 42–43 Practice and Apply 11. WUT and VUX are vertical angles. They each have measures less than 90°, so they are acute. 12. WUV and XUT are vertical angles. They each have measures greater than 90°, so they are obtuse. 13. ZWU is a right angle and ZWU and YWU are supplementary so YWU is a right angle. Then UWT and TWY are adjacent angles that are complementary because mUWT mTWY mYWU. 14. VXU and WYT are nonadjacent angles that are complementary because mVXU mWYT 60 30 or 90. 15. WTY and WTU is a linear pair with vertex T. 16. UVX 17. Explore: The problem relates the measures formed by perpendicular rays. Plan: QP QR, so PQS and SQR are complementary. mPQS mSQR 90

19.

20.

R

S 9 4a

4 7a Q

P

21.

Solve: 4 7a 9 4a ¬90 13 11a ¬90 11a ¬77 a ¬7 mPQS 4 7a 4 7(7) 4 49 or 53

Chapter 1

14

mSQR 9 4a 9 4(7) 9 28 or 37 Examine: Add the angle measures to verify their sum is 90. 53 37 90 Explore: The problem relates the measures of two complementary angles. You know that the sum of the measures of complementary angles is 90. Plan: The angles are complementary, so the sum of the measures of the angles is 90. Solve: 16z 9 4z 3 ¬90 20z 6 ¬90 20z ¬96 z ¬4.8 16z 9 ¬16(4.8) 9 ¬76.8 9 or 67.8 4z 3 ¬4(4.8) 3 ¬19.2 3 or 22.2 Examine: Add the angle measures to verify that the angles are complementary. 67.8 22.2 90 Explore: The problem involves an angle and its supplement. You know that the sum of the measures of two supplementary angles is 180. Plan: Let mT x. Its supplement has measure 180 x. The problem also states that mT is 20 more than four times its supplement. Solve: x ¬4(180 x) 20 x ¬720 4x 20 5x ¬740 x ¬148 So mT 148. Examine: Check to see if the answer satisfies the problem. If mT 148, its supplement has a measure of 32. 4 32 20 148 The answer checks. Explore: The problem involves an angle and its supplement. Plan: Let the measure of one angle be x. Its supplement has measure 180 x. The problem states that the measure of the angle’s supplement is 44 less than x. Solve: 180 x ¬x 44 224 x ¬x 224 ¬2x 112 ¬x 180 x ¬180 112 or 68 The measures of the angle and its supplement are 112 and 68. Examine: 112 44 68 Explore: The problem involves an angle and its supplement. Plan: Let the measure of one angle be x. Its supplement has measure 180 x. The problem states that one angle measures 12° more than the other.

22.

23.

24.

25.

26.

27.

28.

Solve: x 12 ¬180 x x ¬168 x 2x ¬168 x ¬84 180 x 180 84 or 96 The measures of the angle and its supplement are 84 and 96. Examine: 96 84 12 Explore: The problem states that m1 is five less than 4 m2 and 1 and 2 form a linear pair. So m1 m2 180. Plan: Let m1 x. Solve: m1 m2 ¬180 x m2 ¬180 4 m2 5 m2 ¬180 5 m2 ¬185 m2 ¬37 m1 4 m2 5 4(37) 5 148 5 or 143 Examine: 4(37) 5 ¬143 143 ¬143 1 and 2 are supplementary because 143 37 180. Always; the sum of two angles that each measure less than 90° can never equal 180°, so if one angle is acute the other must be obtuse. Always; complementary angles are angles whose measures have a sum of 90°, so each angle must measure less than 90°. Sometimes; for example, consider the following: mA 90 mB 90 mC 90 Then mA mB 180 and mB mC 180 and mA mC 180. However, now consider mA 100 mB 80 mC 100 mA mB 180 and mB mC 180 but mA mC 200, so A is not supplementary to C. Never; P N and P Q have point P in common and form a right angle. NPQ is formed by P N and Q P . Since P is the vertex, NPQ is a right angle. CF FD if CFD is a right angle. So find a so that mCFD 12a 45 is equal to 90. 12a 45 ¬90 12a ¬45 a ¬3.75 mAFC ¬mAFB mBFC 90 ¬8x 6 14x 8 90 ¬22x 2 88 ¬22x 4 ¬x

29. BFA and DFE are vertical angles so they have the same measure. 3r 12 ¬8r 210 3r ¬8r 198 11r ¬198 r ¬18 mBFA 3r 12 3(18) 12 54 12 or 66 BFA and AFE are adjacent supplementary angles, so mBFA mAFE 180. 66 mAFE ¬180 mAFE ¬114 30. ¬L and M are complementary. mL mM ¬90 y 2 2x 3 ¬90 y 2x 1 ¬90 y 2x ¬89 y ¬89 2x N and P are complementary. mN mP ¬90 2x y x 1 ¬90 3x y 1 ¬90 3x y ¬91 y ¬91 3x y ¬3x 91 Equate the two expressions for y and solve for x. 89 2x ¬3x 91 180 2x ¬3x 180 ¬5x 36 ¬x Now substitute the value of x into either expression for y and solve for y. y ¬3x 91 y ¬3(36) 91 y ¬108 91 or 17 mL ¬y 2 mL ¬17 2 or 15 mM ¬2x 3 mM ¬2(36) 3 mM ¬72 3 or 75 mN ¬2x y mN ¬2(36) 17 mN ¬72 17 or 55 mP ¬x 1 mP ¬36 1 or 35 31. Yes; the symbol denotes that DAB is a right angle. 32. Yes; they are vertical angles. 33. Yes; the sum of their measures is mADC, which is 90. 34. No; there is no indication of the measures of these angles. 35. No; we do not know mABC. 36. Sample answer: Complementary means serving to fill out or complete, while complimentary means given as a courtesy or favor. Complementary has the mathematical meaning of an angle completing the measure to make 90°.

15

Chapter 1

37. Sample answer:

52.

EF ¬ [4 (2)]2 [1 0 ( 10)]2

1

EF ¬ (2)2 202

2

EF ¬ 4 400 404 EF ¬20.1

38. mAKB mBKC mCKD 20 25 45 or 90, so AKD is a right angle and A KK D . mDKE mEKF 60 30 or 90, so DKF is a right angle and K D K F . mEKF mFKG 30 60 or 90, so EKG is a right angle and K E K G . 39. Because WUT and TUV are supplementary, let mWUT x and mTUV 180 x. A bisector creates measures that are half of the x original angle, so mYUT 1 2 mWUT or 2 and

41.

42.

43.

GH ¬ (6 7)2 (0 2)2 GH ¬(13) 2 ( 2)2 GH ¬ 169 4 173 GH ¬13.2 54.

2 JK ¬12 (2)2

mYUT mTUZ or 180 x 18 0 x . This sum simplifies to 2 2 2 or 90. Because mYUZ 90, Y U U Z . Sample answer: The types of angles formed depends on how the streets intersect. There may be as few as two angles or many more if there are more than two lines intersecting. Answers should include the following. • linear pairs, vertical angles, adjacent angles • See students’ work. A; my ¬89 and mx my 180. mx ¬180 my mx ¬180 89 or 91 Let x be the number. 4 5 6 ¬2(10 x) 120 ¬20 2x 100 ¬2x 50 ¬x , Lines , m, and n are in plane E, so AB , and n AB . m AB

JK ¬ 144 4 148 JK ¬12.2 2 2 d ¬(x 2 x 1) (y 2 y 1)

55.

LM ¬ (3 1 )2 ( 1 3)2 2 (4) LM ¬2 2 4 16

LM ¬20 LM ¬4.5 56.

3x 1x

P

4x 17

Q

R

PR ¬PQ QR 3x ¬1 x 4x 17 3x ¬3x 18 6x ¬18 x ¬3 QR ¬4x 17 QR ¬4(3) 17 QR ¬12 17 or 5 57.

mKFG 90, so KFG is acute. mHFG 90, so HFG is obtuse. mHFK 90, so HFK is a right angle. JFE is marked with a right angle symbol, so JFE is a right angle. 48. mHFJ 90, so HFJ is acute. 49. mEFK 90, so EFK is obtuse. 44. 45. 46. 47.

7n 8 4n 3

P

6n 2

Q

R

PR ¬PQ QR 7n 8 ¬4n 3 6n 2 7n 8 ¬10n 1 7n 9 ¬10n 9 ¬3n 3 ¬n QR ¬6n 2 QR ¬6(3) 2 QR ¬18 2 or 20 58. ¬3, w 8 2 2w ¬2(3) 2(8) ¬6 16 or 22 59. ¬3, w 8 w ¬3 8 ¬24

2 2 d ¬(x 2 x 1) (y 2 y 1)

AB ¬ (0 3 )2 (1 5)2 2 AB ¬(3) (4 )2

AB ¬9 16 25 AB ¬5 2 2 51. d ¬ (x2 x y2 y 1) ( 1) 2 (9 CD ¬ (5 5) 1)2

CD ¬ 02 82 64 CD ¬8

Chapter 1

2 2 d ¬(x 2 x 1) (y 2 y 1) 2 JK ¬ [4 (8)] (7 9)2

Page 43 Maintain Your Skills

50.

2 2 d ¬(x 2 x 1) (y 2 y 1)

53.

180 x mTUZ 1 . Then mYUZ 2 mTUV or 2

40.

2 2 d ¬(x 2 x 1) (y 2 y 1)

16

s ¬2 4s ¬4(2) ¬8 61. 3, w ¬8, s 2 w ws ¬3 8 8 2 ¬24 16 or 40 62. 3, w ¬8, s 2 s( w) ¬2(3 8) ¬2(11) or 22

2 PS ¬[0 3)] ( (4 4)2 2 2 ¬ 3 0 ¬ 93 Perimeter PQ QR RS PS 5 3 5 3 or 16 units 10. AB BC CD AD ¬95 3a 2 2(a 1) 6a 4 5a 5 ¬95 3a 2 2a 2 6a 4 5a 5 ¬95 16a 1 ¬95 16a ¬96 a ¬6 AB 3a 2 BC ¬2(a 1) 3(6) 2 ¬2(6 1) 18 2 20 ¬2(5) 10 CD 6a 4 AD ¬5a 5 6(6) 4 ¬5(6) 5 36 4 40 ¬30 5 25 11. P 5s 5(921) 4605 The perimeter of the outside of the Pentagon is 4605 feet.

60.

Page 44 Geometry Activity: Constructing Perpendiculars 1. See students’ work. 2. The first step of the construction locates two points on the line. Then the process is very similar to the construction through a point on a line.

1-6

Polygons

Page 48 Check for Understanding 1. A regular decagon has 10 congruent sides, so divide the perimeter by 10. 2. Saul; Tiki’s figure is not a polygon. 3. P 3s 4. Sample answer: Some of the lines containing the sides pass through the interior of the pentagon.

Pages 49–50 Practice and Apply 12. There are 4 sides, so the polygon is a quadrilateral. No line containing any of the sides will pass through the interior of the quadrilateral, so it is convex. The sides are congruent but the angles are not so it is irregular. 13. There are 8 sides, so the polygon is an octagon. No line containing any of the sides will pass through the interior of the octagon, so it is convex. The sides are congruent, and the angles are congruent, so it is regular. 14. There are 10 sides, so the polygon is a decagon. A line containing any of the sides will pass through the interior of the decagon, so it is concave. The sides are congruent, but the decagon is concave so it cannot be regular. It is irregular. 15. There are 5 sides, so the sign is a pentagon. 16. There are 4 sides, so the sign is a quadrilateral. 17. There are 3 sides, so the sign is a triangle. 18. There are 12 sides, so the sign is a dodecagon. 19. P 2 2w 2(28) 2(13) 56 26 82 ft 20. P 6 12 8 15 15 56 m 21. P 6 2 2 6 2 2 6 2 2 6 2 2 40 units 22. The new length would be 4(28) or 112 feet. The new width would be 4(13) or 52 feet. P 2 2w 2(112) 2(52) 328 The perimeter is multiplied by 4. 23. The new side lengths are 18 m, 36 m, 24 m, 45 m, and 45 m. The new perimeter is 18 36 24 45 45 or 168 m. The perimeter is tripled.

5. There are 5 sides, so the polygon is a pentagon. A line containing side N M will pass through the interior of the pentagon, so it is concave. The sides are not congruent, so it is irregular. 6. There are 6 sides, so the polygon is a hexagon. No line containing any of the sides will pass through the interior of the hexagon, so it is convex. The sides are congruent, and the angles are congruent, so it is regular. 7. Perimeter 8 8 6 5 6 33 ft 8. The new side lengths would be 16 ft, 16 ft, 12 ft, 10 ft, and 12 ft so the new perimeter would be 16 16 12 10 12 66 ft. The perimeter doubles. 2 2 9. d ¬ (x2 x y2 y 1) ( 1) 2 PQ ¬[[0 3)] ( (8 4)2 2 2 ¬ 3 4 ¬ 25 5 2 (8 QR ¬(3 ) 0 8)2 2 2 ¬ 3 0 ¬ 9 or 3 2 (4 RS ¬(0 ) 3 8)2 2 2 ¬(3) ) (4 ¬ 25 5

17

Chapter 1

24. The new side lengths are 3 and 1 units. The new perimeter is 3 1 1 3 1 1 3 1 1 3 1 1 or 20 units. The perimeter is divided by 2. 25. The length of each side is multiplied by 10, so 10 can be factored out of the sum of the sides. Thus the new perimeter is multiplied by 10 so the perimeter is 12.5(10) 125 m. 2 2 26. d ¬(x 2 x 1) (y 2 y 1) 2 AB ¬[3 1)] ( (4 1)2 2 2 ¬ 4 3 ¬ 25 5 2 (0 BC ¬(6 ) 3 4)2 2 2 ¬3 ( 4) ¬ 25 5 CD ¬ (2 6 )2 ( 3 0)2 2 2 ¬(4) (3) ¬ 25 5 AD ¬[2 ( 1)]2 (3 1)2 2 2 ¬3 ( 4) ¬ 25 5 The perimeter is AB BC CD AD 5 5 5 5 or 20 units. 2 2 27. d ¬(x 2 x 1) (y 2 y 1) 2 PQ ¬ [3 ( 2)] (3 3)2 2 2 ¬5 0 ¬ 25 5 2 (0 QR ¬ (7 3) 3)2 2 2 ¬4 ( 3) ¬ 25 5 RS ¬ (3 7 )2 ( 3 0)2 2 2 ¬(4) (3) ¬ 25 5 ST ¬ (2 3)2 [3 (3)]2 2 2 ¬(5) 0 ¬ 25 5 TU ¬ [6 (2)]2 [0 (3 )]2 2 2 ¬(4) 3 ¬ 25 5 PU ¬ [6 (2)]2 (0 3)2 2 2 ¬(4) (3) ¬ 25 5 The perimeter is PQ QR RS ST TU PU or 5 5 5 5 5 5 30 units. 2 2 28. d ¬ (x2 x y2 y 1) ( 1) 2 VW ¬ (2 3) (12 0)2 2 2 ¬ (5) 12 ¬ 169 13 2 ( WX ¬ [10 (2)] 3 12)2 2 2 ¬ (8) (1 5) ¬ 289 17 2 [ XY ¬ [8 (10)] 12 (3)]2 2 2 ¬ 2 (9) ¬ 85 YZ ¬ [2 (8)]2 [ 12 ( 12)]2 2 2 ¬6 0 ¬ 36 6

Chapter 1

29. 30. 31.

32.

33.

34.

35. 36.

VZ ¬ (2 3)2 (12 0)2 2 2 ¬(5) (12) ¬ 169 13 The perimeter is VW WX XY YZ VZ or 13 17 85 6 13 58.2 units. There are 6 sides and all sides are congruent. 9 0 All sides are 6 or 15 cm. There are 4 sides and all sides are congruent. 1 4 All sides are 4 or 3.5 mi. P ¬x 1 x 7 3x 5 31 ¬5x 1 30 ¬5x 6 ¬x x 1 ¬6 1 5 x 7 ¬6 7 13 3x 5 ¬3(6) 5 13 The sides are 13 units, 13 units, and 5 units. P ¬6x 3 8x 3 6x 4 84 ¬20x 4 80 ¬20x 4 ¬x 6x 3 6(4) 3 21 8x 3 8(4) 3 35 6x 4 6(4) 4 28 The sides are 21 m, 35 m, and 28 m. P ¬2 2w 42 ¬2(3n 2) 2(n 1) 42 ¬6n 4 2n 2 42 ¬8n 2 40 ¬8n 5 ¬n 3n 2 ¬3(5) 2 17 n 1 ¬5 1 4 The sides are 4 in., 4 in., 17 in., and 17 in. P ¬2x 1 2x x 2x 41 ¬7x 1 42 ¬7x 6 ¬x 2x 1 ¬2(6) 1 11 2x ¬2(6) 12 The sides are 6 yd, 11 yd, 12 yd, and 12 yd. 52 units; count the units in the figure. 5 squares 8 squares

9 squares

36a. It is a square with side length of 3 units. 36b. In Part a, the rectangle with the greatest number of squares was a square with side of 3 units. So if a rectangle has perimeter of 36 units, a square would have the largest area. The side of 3 6 this square would be 4 9 units.

18

37. Sample answer: Some toys use pieces to form polygons. Others have polygon-shaped pieces that connect together. Answers should include the following. • triangles, quadrilaterals, pentagons •

Page 52 Geometry Software Investigation: Measuring Polygons 1. The sum of the side measures equals the perimeter. 2. 35.53 90.38 54.09 180 3. See students’ work. 4. Sample answer: When the lengths of the sides are doubled, the perimeter is doubled. 5. See student’s work. 6. Sample answer: The sum of the measures of the angles of a triangle is 180. 7. Sample answer: The sum of the measures of the angles of a quadrilateral is 360; pentagon 540; hexagon 720. 8. Sample answer: The sum of the measures of the angles of polygons increases by 180 for each additional side. 9. yes; sample answer: triangle: 3 sides, angle measure sum: 180; quadrilateral: 4 sides, angle measure sum: 180 180 360; pentagon: 5 sides, angle measure sum: 360 180 540; hexagon: 6 sides, angle measure sum: 540 180 720 10. Yes; sample answer: If the sides of a polygon are a, b, c, and d, then its perimeter is a b c d. If each of the sides are increased by a factor of n then the sides measure na, nb, nc, and nd, and the perimeter is na nb nc nd. By factoring, the perimeter is n(a b c d), which is the original perimeter increased by the same factor as the sides.

38. A square has four congruent sides. If one side remains to be fenced, three sides have been fenced. So each side has length 1 3 (3x) or x meters. 39. D; 5n 5 ¬10 5n ¬5 n ¬1 11 n ¬11 1 10

Page 50 Maintain Your Skills 40. Always; true by the definitions of linear pairs and supplementary angles. 41. Sometimes; angles with measures 100 and 80 are supplementary but two right angles are also supplementary. 42. AM bisects RAL, so MAR MAL. mMAR ¬mMAL 2x 13 ¬4x 3 2x 16 ¬4x 16 ¬2x 8 ¬x mRAL ¬mMAR mMAL ¬2x 13 4x 3 ¬2(8) 13 4(8) 3 or 58 43. AM bisects RAL, so MAR LAM and mRAL ¬2 mMAR. x 32 ¬2(x 31) x 32 ¬2x 62 x 94 ¬2x 94 ¬x mLAM mMAR ¬x 31 ¬94 31 63 bisects MAR, so RAS SAM. 44. AS AM bisects LAR, so mLAR 2 mMAR. mRAS ¬mSAM 25 2x ¬3x 5 20 2x ¬3x 20 ¬5x 4 ¬x mLAR ¬2 mMAR ¬2(mSAM mRAS) ¬2(3x 5 25 2x) ¬2(x 30) ¬2x 60 ¬2(4) 60 68

Chapter 1 Study Guide and Review Pages 53–56 1. 2. 5. 8. 11.

d; A B B C , so h b K or L C

B is the midpoint of A C . 3. f 4. e 6. g 7. p or m 9. F 10. S 12. S T U

m 13.

V

25 3x

7 A

P

B

AB ¬AP PB 25 ¬7 3x 18 ¬3x 6 ¬x PB ¬3x ¬3(6) ¬18

19

Chapter 1

14.

23.

9 4c

MP ¬ [6 (4)]2 (1 9 16)2 2 2 ¬(2) 3 13 ¬3.6

2c

A

P

x x

B

8s 7

s2 A

4s

P

B

AB ¬AP PB 8s 7 ¬s 2 4s 8s 7 ¬5s 2 8s ¬5s 9 3s ¬9 s ¬3 PB ¬4s ¬4(3) ¬12 16.

A

17. 18. 19. 20.

2

1

2

1

2

1

2

1

2

1

2

, FG D 29. FE 30. DEH 70°; 70 90, so SQT is acute. 110°; 110 90 and 110 180, so PQT is obtuse. 50°; 50 90, so T is acute. 70°; 70 90, so PRT is acute. XV bisects YXW, so YXV VXW. mYXV ¬mVXW 3x ¬2x 6 x ¬6 mYXW ¬mYXV mVXW ¬3x 2x 6 ¬3(6) 2(6) 6 ¬36 36. XW bisects YXZ, so YXW WXZ. mYXW ¬mWXZ 12x 10 ¬8(x 1) 12x 10 ¬8x 8 12x ¬8x 18 4x ¬18 x ¬9 2 mYXZ ¬mYXW mWXZ ¬12x 10 8(x 1) 9 ¬12 9 2 10 8 2 1 ¬54 10 44 ¬88

k6

P B

AB ¬AP PB 11 ¬2k k 6 11 ¬k 6 5 ¬k 5 ¬k PB ¬k 6 ¬5 6 ¬1 yes, because HI KJ 9 m no, because AB 13.6 cm and AC 19.3 cm not enough information to determine if 5x 1 4x 3 2 2 d ¬(x 2 x 1) (y 2 y 1)

AB ¬ (3 1)2 (2 0 )2 2 2 ¬(4) 2 20 ¬4.5 2 2 21. d ¬(x 2 xy 1) ( 2 y 1)

GL ¬[3 ( 7)]2 (3 4)2 2 2 ¬10 (1) ¬ 101 ¬10.0 2 2 22. d ¬(x 2 x 1) (y 2 y 1) 2 ( JK ¬ (4 0) 1 0)2 2 2 ¬4 ( 1) ¬ 17 ¬4.1

Chapter 1

1

28. 31. 32. 33. 34. 35.

11 2k

y y

2 2 0 22 0 (18) ¬2, 2 22 18 ¬2, 2 or (11, 9) x x y y 25. M ¬, 2 2 6 12 3 (7) ¬2, 2 6 10 ¬2, 2 or (3, 5) x x y y 26. M ¬, 2 2 2 (1) 5 (1) ¬2, 2 1 4 ¬2, 2 or (0.5, 2) x x y y 27. M ¬, 2 2 3.4 (2.2) 7.3 (5.4) ¬ , 2 2 1.2 12.7 ¬2, 2 or (0.6, 6.35) 1 2 1 2 24. M ¬ ,

AB ¬AP PB 9 ¬4c 2c 9 ¬6c 3 ¬c or c 1.5 2 PB ¬2c ¬2 3 2 ¬3 15.

2 2 d ¬(x 2 x 1) (y 2 y 1)

20

37. XW bisects YXZ, so YXW WXZ and mWXZ ¬1 2 mYXZ.

2 WX¬[7 3)] ( (1 5)2 2 2 ¬ 10 (4) 116 XY ¬ (5 7 )2 ( 4 1)2 ¬ (2)2 (5 )2 29 2 YZ ¬ (5 5) [0 (4)] 2 2 2 ¬ (10) 4 116 WZ ¬ [5 (3)]2 (0 5)2 ¬ (2)2 (5 )2 29 Perimeter ¬WX XY YZ WZ ¬ 116 29 116 29 ¬32.3 units

mWXZ ¬1 2 mYXZ 7x 9 ¬1 2 (9x 17) 17 7x 9 ¬9 2 x 2 35

9 7x ¬ 2 x 2 5 35 x ¬ 2 2

38. 40.

41.

42.

43. 44.

45.

2 2 d ¬(x 2 x 1) (y 2 y 1)

46.

x ¬7 mYXW ¬mWXZ ¬7x 9 ¬7(7) 9 ¬40 TWY, WYX 39. TWY, XWY W T W Z if mTWZ 90. mTWZ ¬2c 36 90 ¬2c 36 54 ¬2c 27 ¬c ZWX ¬ZWY YWX 90 ¬4k 2 5k 11 90 ¬9k 9 81 ¬9k 9 ¬k There are 4 sides, so the polygon is a quadrilateral. No line containing any of the sides will pass through the interior of the quadrilateral, so it is convex. The sides are congruent, and the angles are congruent, so it is regular. The figure is not a polygon because there are sides that intersect more than two other sides. There are 8 sides, so the polygon is an octagon. There is a side such that a line containing that side will pass through the interior of the octagon, so it is concave. The sides are not congruent, so the octagon is irregular. 2 2 d ¬(x 2 x 1) (y 2 y 1)

Chapter 1 Practice Test Page 57 1. true 2. true 3. False; the sum of two supplementary angles is 180. 4. true 5. m 6. D 7. C 8. 29 2 3x

UV

W

UW ¬UV VW 29 ¬2 3x 27 ¬3x 9 ¬x VW ¬3x ¬3(9) 27 9.

2 (1 AB ¬ (5 1) 2)2 2 (1) ¬4 2 17 2 BC ¬ (9 5) (2 1)2 2 2 ¬4 1 17 2 (5 CD ¬ (9 9) 2)2 2 32 ¬0 3 2 (6 DE ¬ (5 9) 5)2 2 2 ¬ (4) 1 17 2 (5 EF ¬ (1 5) 6)2 2 ) ¬ (4) (12 17 2 2 AF ¬ (1 1) (5 2) 2 32 ¬0 3 Perimeter ¬AB BC CD DE EF AF ¬ 17 17 3 17 17 3 ¬6 4 17 ¬22.5 units

42

r U

6r V

W

UW ¬UV VW 42 ¬r 6r 42 ¬7r 6 ¬r VW ¬6r ¬6(6) 36 10.

15 4p 3

U

5p

V

W

UW UV VW 15 ¬4p 3 5p 15 ¬9p 3 18 ¬9p 2 ¬p VW ¬5p ¬5(2) 10

21

Chapter 1

11.

2 (4) ¬0 2 4 DE ¬ (4 0)2 (3 0)2 2 ¬(4) (3)2 25 5 2 AE ¬ [4 (6)] ( 3 2)2 2 2 ¬2 (5) 29 Perimeter ¬AB BC CD DE AE ¬29 5 4 5 29 ¬24.8 units

4c 3c 29

U

2c 4

V

W

UW ¬UV VW 4c ¬3c 29 (2c 4) 4c ¬c 25 5c ¬25 c ¬5 VW ¬2c 4 ¬2(5) 4 6 2 2 12. d ¬(x 2 x 1) (y 2 y 1)

23.

B

GH ¬ (3 0)2 (4 0)2 2 2 ¬ (3) 4 25 ¬5 2 2 13. d ¬ (x2 x y2 y 1) ( 1)

C

NK ¬ (2 5)2 (8 2)2 2 2 ¬ (7) 6 85 ¬9.2 2 2 14. d ¬ (x2 x y2 y 1) ( 1)

15. 17. 19.

20.

21.

S

AW ¬ [2 (4)]2 [2 (4)] 2 2 2 ¬ 2 6 40 ¬6.3 C 16. EC, ED ABD or ABE 18. 9 4r 7 r 2¬ 180 5r 5¬ 180 5r¬ 175 r¬ 35 4r 7 ¬4(35) 7 or 147 r 2 ¬35 2 or 33 Let x be the measure of one angle. Then the other angle has measure x 26 and x x 26 90. x x 26¬ 90 2x 26¬ 90 2x¬ 64 x¬ 32 x 26 32 26 58

24.

B

C

S

2 2 d ¬(x 2 x 1) (y 2 y 1)

AB ¬ [4 (6)]2 (7 2)2 2 2 ¬2 5 29 BC ¬ [0 ( 4)]2 (4 7)2 2 (3) ¬4 2 ¬ 25 5 2 (0 CD ¬ (0 0) 4)2 Chapter 1

X Y

Use the information known about the cities to place them on a coordinate plane. Then use the gridlines to form a triangle using the points S for Springfield, C for Capital City, and X. Use the Pythagorean Theorem. (SC)2 ¬(SX)2 (CX)2 (SC)2 ¬52 32 (SC)2 ¬34 SC ¬5.8 Highway 4 is approximately 5.8 miles long. 25. C; the figure has sides with a common endpoint that are collinear.

2 2 d ¬(x 2 x 1) (y 2 y 1)

PQ ¬ [1 ( 6)]2 [1 (3)] 2 2 2 ¬7 2 53 2 [ QR ¬ (1 1) 5 (1)] 2 2 (4) ¬0 2 4 PR ¬ [1 ( 6)]2 [5 (3)] 2 2 2 ¬7 (2) 53 Perimeter ¬PQ QR PR ¬ 53 4 53 ¬18.6 units 22.

X Y

Use the information known about the cities to place them on a coordinate plane. Then use the gridlines to form a triangle using the points S for Springfield, B for Brighton, and Y. Use the Pythagorean Theorem. (SB)2 ¬(SY)2 (BY)2 (SB)2 ¬62 72 (SB)2 ¬85 SB ¬9.2 Highway 1 is approximately 9.2 miles long.

22

y ¬2x 3 y ¬2(2) 3 or 7 The solution is (2, 7).

Chapter 1 Standardized Test Practice Pages 58–59

12.

1. C; there are 15 hours between 7 A.M. and 10 P.M., so there are 15 60 900 minutes during that time. Then Juanita blinks 11 900 or 9900 times during the time she is awake. 2. A 2(x2 6x 8) 2x2 12x 16 3. B; ¬ 2x 4 2(x 2)

y

B

C

x

O

A

2(x 4)(x 2) ¬ 2(x 2) ¬x 4

D

ABCD is a rectangle, so D must have coordinates D(3, 1).

4. A; three noncollinear points determine a plane, so if the two planes are distinct, their intersection is not a plane. Two planes intersect in only one line. 5. B; 1 fathom 6 feet so 55 fathoms 55(6) or 330 feet, which is 110 yards. 6. C; use the Pythagorean Theorem, where x is the height up the side of the house that the ladder reaches. (18)2 ¬(6)2 x2 324 ¬36 x2 288 ¬x2 17.0 ¬x 7. C; mABD ¬mCBD 2x 14 ¬5x 10 2x 14 10 ¬5x 10 10 2x 24 ¬5x 2x 24 2x ¬5x 2x 24 ¬3x 8 ¬x mABD 2x 14 2(8) 14 30 8. D; let x be the measure of FEG. mDEG mFEG ¬180

x x

y y

2 2 (4) 2 1 3 2, 2 2 2 2, 2 (1, 1)

1 2 1 2 13. M ,

14. (AB)2 ¬602 1102 (AB)2 ¬3600 12,100 (AB)2 ¬15,700 AB ¬125 m 15. P 2 2w 2(16) 2(24) 80 The perimeter of the basement is 80 feet. If the 8 0 pieces of plasterboard are 4 feet wide, it takes 4 or 20 pieces of plasterboard to cover the walls. 16a. y

x

O

612x x ¬180 15 2 x ¬180

x x y y 2 2 4 4 0 0 ¬(2, 2) 2 , 2 (4) 4 0 0 , 2 ¬(2, 2) 2 0 0 (4) 4 2, 2 ¬(2, 2) 0 04 4 2 , 2 ¬(2, 2)

9. D;

treasure

17a. You are given that a 25. The measure of the other angle marked with a single arc is also 25 because the arcs tell us that the angles are congruent. Both of the angles marked with double arcs have a measure of a 10, which is 25 10 or 35. In the remaining angle, b 180 (25 35 25 35) or 60 because the angles can be combined to form linear pairs, which are supplementary. 17b. All are acute.

115 Kaitlin

1 2 1 2 , 16b. M ¬

x ¬24 mDEG ¬61 2 (24) ¬156

Henry

If Kaitlin turns 115°, Henry turns 180° 115° or 65°. 10. 2x 6 4x2 x x2 5 5x2 x 1 11. 2y ¬3x 8 y ¬2x 3 2(2x 3) ¬3x 8 4x 6 ¬3x 8 x ¬2

23

Chapter 1

Chapter 2 Reasoning and Proof Page 61

Getting Started

2-1

1. 3n 2 3(4) 2 12 2 10 2. (n 1) n (6 1) 6 76 13 3. n2 3n (3)2 3(3) 9 3(3) 990 4. 180(n 2) 180(5 2) 180(3) 540

Pages 63–64 Check for Understanding 1. Sample answer: After the news is over, it’s time for dinner. 2. Sometimes; the conjecture is true when E is between D and F; otherwise it is false. 3. Sample answer: When it is cloudy, it rains. Counterexample: It is often cloudy and it does not rain. 4. There is one of each shape in the first figure. There are two of each shape in the second figure and three of each shape in the third figure. So the next figure will have four of each shape.

10 5. nn 2 ¬10 2

¬10(5) 50 n(n 3) 8(8 3) 6. 2 ¬ 2 8(5) ¬ 2 4 0 ¬2 20

8 5 2 1 4

5.

7. 6x 42 ¬4x 42 ¬2x 21 ¬x 8. 8 3n ¬2 2n 10 3n ¬2n 10 ¬5n 2 ¬n 9. 3(y 2) ¬12 y 3y 6 ¬12 y 3y ¬18 y 2y ¬18 y ¬9 10. 12 7x ¬x 18 7x ¬x 30 6x ¬30 x ¬5

3

3

3

3

The numbers in the sequence increase by 3. The next number will increase by 3. So, it will be 4 3 or 7. 6. PQ TU P Q R

S

T

U

7. AB and CD intersect at a single point P, so the lines are distinct. Thus the points A, B, C, and D are not all on the same line. So, A, B, C, and D are noncollinear. A

11. 3x 4 ¬1 2x 5

D P

3x ¬1 2x 9

C

5x ¬9 2 18 x ¬ 5 2 12. 2 2x ¬3x 2 4 2x ¬2 3x 4 ¬8 3x 3 ¬x 2

B

8. False; if x 2, then x (2) or 2. 9. True; opposite sides of a rectangle are congruent, and the sides of the rectangle can be determined from the order of the letters in its name. 10. Sample answer: Snow will not stick on a roof with a steep angle.

13. AGB and EGD are vertical angles, so mAGB mEGD. 4x 7 ¬71 4x ¬64 x ¬16 14. mBGC mCGD mDGE 180 45 8x 4 15x 7 ¬180 23x 42 ¬180 23x ¬138 x ¬6

Chapter 2

Inductive Reasoning and Conjecture

Pages 64–66 Practice and Apply 11. Each figure is formed by adding another row of dots to the top and another column of dots on the side. The number of dots in each figure is 2, 6, 12, 20. 2 6 12 20 4

24

6

8

The numbers increase by 4, 6, and 8. The next number will increase by 10. So, it will be 30.

20. Each arrangement of blocks is formed by adding a level of blocks to the bottom. The number of blocks on the bottom level of the figures is 1, 3, and 6. 1 3 6 2

12. Each figure adds a triangle and changes the orientation of the triangles. The next figure will have five triangles with the same orientation as the three triangles in the second figure.

13.

1 2 4 8 16 1

2

4

8

The numbers increase by 1, 2, 4, and 8, which are the first four numbers in the sequence. The next number will increase by the fifth number in the sequence, or 16. So, the next number will be 16 16 or 32. 14. 4 6 9 13 18 2

3

4

21. Perpendicular lines form four right angles, so lines and m form four right angles.

5

The numbers increase by 2, 3, 4, and 5. The next number will increase by 6. So, it will be 18 6 or 24. 15.

3

The number of blocks on the bottom increase by 2 and 3. The next increase will be 4. So there will be 10 blocks on the bottom of the fourth figure. The upper levels of the figure have a total of 10 blocks. The total number of blocks in this figure is 20.

m 22. Graph A, B, and C. Connect the points to see that they lie on the same line. Thus A, B, and C are collinear.

1 3

5 7 1 3 3 3 2 2 2 2 3

3

3

3

y

The numbers increase by 2 3 . The next number will 1 1 or be 3 2 . 3 3

16.

8

1 1 1 1 1 16 2 4 8 1 1 1 1 2

2

2

4

B(2, 1)

2

The numbers are multiplied by 1 2 . The next 1 1 1 number will be or . 16 32 2

17.

–8

O

–4

(5)

A(–2, –11) 23. Linear pairs of angles are supplementary, so 3 and 4 are supplementary.

(5)

The numbers are multiplied by 5. The next number will be 625 (5) or 3125. 19. Each arrangement of blocks is formed by adding a level of blocks to the bottom. The numbers of blocks in the sequence are 1, 5, and 14. 1 5 14 4

8x

–8

(3) (3)

The numbers are multiplied by 3. The next number will be 54 (3) or 162. 18. 5 25 125 625 (5)

4

–4

2 6 18 54 (3)

C (5, 10)

3

4

24. BD bisects ABC so the two angles formed are congruent: ABD DBC. A D

9

The numbers increase by 4 and 9, which are squares of 2 and 3, respectively. The next number will increase by the square of 4, or 16. So it will be 14 16 or 30.

B

C

25. Graph P, Q, and R. The points form a triangle. Find the distance between each pair of points to determine the type of triangle. 2 d (x x (y2 y1)2 2 1) 2 PQ [6 1)] ( (2 7)2 2 2 7 9) ( 130 2 [5)] QR (6 ) 6 (22 2 2 0 7 49 or 7

25

Chapter 2

2 PR [6 1)] ( (5 7)2 2 ( 2 7 2) 53 The lengths PQ, QR, and PR are all different, so PQR is a scalene triangle.

33.

y

P

34. 35. 36.

R(6, 5)

(–1, 7)

37. 38.

x

O

Q (6, –2)

26. A square has 4 congruent sides. From the name of the square the sides are H I, IJ , J K , and K H . Thus, HI IJ JK KH. H I

H

K J 27. A rectangle has 4 sides where opposite sides are congruent. From the name of the rectangle the sides are P Q , QR , S R , and P S . The pairs of opposite sides are P Q , S R and Q R , P S . Thus, PQ SR and QR PS. P Q

C

29. False;

1

2

30. False; if y 7 and m 5, then 7 5 10 and 5 4, but 7 6. 31. False; W X Y Z 32. True; y

A

B

C

x O

Chapter 2

C

C

C

C

H

H

H

H

H

39. The 1st alkane has formula CH4 (or C1H4). The 2nd alkane has formula C2H6. The 3rd alkane has formula C3H8. The subscripts for C increase by 1 and are the same number as the number of the alkane in the series. The subscripts for H increase by 2. So the 7th alkane in the series has formula C7H(8 2 2 2 2) or C7H16. 40. The nth alkane has n carbon atoms so the subscript for C is n. The number of hydrogen atoms in the nth alkane is 2 more than twice the numbers of the alkane in the series, or 2n 2. So the subscript for H is 2n 2. The formula is CnH2n 2. 41. False; if n 41, then n2 n 41 (41)2 41 41 or 412, which is not prime. 42. Sample answer: By past experience, when dark clouds appear, there is a chance of rain. Answers should include the following. • When there is precipitation in the summer, it is usually rain because the temperature is above freezing. When the temperature is below freezing, as in the winter, ice or snow forms. • See students’ work. 43. C; 1, 1, 2, 3, 5, 8 112 123 235 358 Each number in the sequence is found by adding the two numbers before it. 5 8 13, so the next number in the sequence is 13. 44. D; Let x be the sum of the six numbers and y be the sum of the three numbers whose average is 15. x 6 18 x 18(6) or 108

S R 28. A triangle that has a right angle is a right triangle. The Pythagorean Theorem is true for every right triangle. Since B is the right angle of the triangle, the hypotenuse is A C and the legs are A B and B C . So (AB)2 (BC)2 (AC)2. A

B

AB is horizontal, and B C is vertical. So the segments are perpendicular to each other. So B is a right angle. Therefore, ABC is a right triangle. True; the square of any real number is a nonnegative number. False; D, E, and F do not have to be collinear. False; JKLM may not have a right angle. True; any three noncollinear points form a triangle. trial and error, a process of inductive reasoning The first three alkanes have 1, 2, and 3 carbon atoms. The fourth alkane will have 4 carbon atoms. The first three alkanes have 4, 6, and 8 hydrogen atoms. The fourth alkane, butane, will have 8 2 or 10 hydrogen atoms. H H H H

26

y 3 15

59. PN 3x and PN 24. 3x ¬24 x ¬8 MP ¬7x ¬7(8) or 56 60. PN 9c and PN 63. 9c ¬63 c ¬7 MP ¬2c ¬2(7) or 14 61. MN MP PN 36 ¬4x 5x 36 ¬9x 4 ¬x MP 4x ¬4(4) or 16 62. MN MP PN 60 ¬6q 6q 60 ¬12q 5 ¬q MP 6q ¬6(5) or 30 63. MN MP PN 63 ¬4y 3 2y 63 ¬6y 3 60 ¬6y 10 ¬y MP 4y 3 ¬4(10) 3 ¬43 64. MN MP PN 43 ¬2b 7 8b 43 ¬10b 7 50 ¬10b 5 ¬b MP ¬2b 7 ¬2(5) 7 ¬3 65. x 2 5 2 2 4. 4 5. So 2 2 5. 3 2 5. 5 5. So 3 2 5. 4 2 6. 6 5. So 4 2 5. 5 2 7. 7 5. So 5 2 5. The values in the replacement set that make the inequality true are 4 and 5. 66. 12 x 0 12 11 1. 1 ¬0. So 12 11 0. 12 12 0. 0 ¬0. So 12 12 0. 12 13 1. 1 ¬0. So 12 13 0. 12 14 2. 2 ¬0. So 12 14 0. The values in the replacement set that make the inequality true are 13 and 14. 67. 5x 1 25 5(4) 1 21. 21 25. So 5(4) 1 25. 5(5) 1 26. 26 25. So 5(5) 1 25. 5(6) 1 31. 31 25. So 5(6) 1 25. 5(7) 1 36. 36 25. So 5(7) 1 25. The values in the replacement set that make the inequality true are 5, 6, and 7.

y 15(3) or 45 The sum of the remaining three numbers is 108 45 or 63.

Page 66 Maintain Your Skills 45. There are 6 sides, so the polygon is a hexagon. No line containing any of the sides will pass through the interior of the hexagon, so it is convex. Not all sides are congruent, so the hexagon is irregular. 46. There are 5 sides, so the polygon is a pentagon. No line containing any of the sides will pass through the interior of the pentagon, so it is convex. The sides and angles are congruent, so the pentagon is regular. 47. There are 7 sides, so the polygon is a heptagon. There is a side such that a line containing the side will pass through the interior of the heptagon, so it is concave. Not all sides are congruent, so the heptagon is irregular. 48. Yes; the symbol denotes that KJN is a right angle. 49. No; we do not know anything about the angle measures. 50. No; we do not know whether MNP is a right angle. 51. Yes; they form a linear pair. 52. Yes; since the other three angles in rectangle KLPJ are right angles, KLP must also be a right angle. x x y y 2 2 1 5 3 (5) 2 , 2 2 4 2 , 2 or (2, 1) x1 x2 y1 y2 M , 2 2 4 (3) 1 2, 2 7 8 1 2 , 2 or (0.5, 4) x1 x2 y1 y2 M , 2 2 4 (2) 9 (15) 2, 2 24 2 2 , 2 or (1, 12) x1 x2 y1 y2 M , 2 2 5 7 4 2 , 22 2 2 2 , 2 or (1, 1) x1 x2 y1 y2 M , 2 2 3 8 1.8 6.2 2, 2 1 1 4.4 2 , 2 or (5.5, 2.2) x1 x2 y1 y2 M , 2 2 (4) 1.5 6 3 2, 2 3 5 .5 2 , 2 or (2.75, 1.5)

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Chapter 2

2-2

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Logic

Pages 71–72 Check for Understanding 1. The conjunction (p and q) is represented by the intersection of the two circles. 2a. Sample answer: October has 31 days or 5 3 8. 2b. Sample answer: A square has five right angles and the Postal Service does not deliver mail on Sundays. 2c. Sample answer: July 5th is not a national holiday. 3. A conjunction is a compound statement using the word and, while a disjunction is a compound statement using the word or. 4. 9 5 14 and February has 30 days.; false, because p is true and q is false 5. 9 5 14 and a square has four sides.; true, because p is true and r is true 6. February has 30 days and a square has four sides.; false, because q is false and r is true 7. 9 5 14 or February does not have 30 days.; true, because p is true and q is true 8. February has 30 days or a square has four sides.; true, because r is true 9. 9 5 14 or a square does not have four sides.; false, because p is false and r is false 10. p q q p q

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Chapter 2

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15. The states that produce more than 100 million bushels of corn are represented by the set labeled Corn. There are 14 states that produce more than 100 million bushels of corn. 16. The states that produce more than 100 million bushels of wheat are represented by the set labeled Wheat. There are 7 states that produce more than 100 million bushels of wheat. 17. The states that produce more than 100 million bushels of corn and wheat are represented by the intersection of the sets. There are 3 states that produce more than 100 million bushels of corn and wheat.

Pages 72–74

Practice and Apply

18. 64 8 and an equilateral triangle has three congruent sides; false, because p is false and q is true. 19. 64 8 or an equilateral triangle has three congruent sides; true, because q is true. 20. 64 8 and 0 0; false, because p is false and r is false. 21. 0 0 and an obtuse angle measures greater than 90° and less than 180°; false, because r is false and s is true. 22. An equilateral triangle has three congruent sides or 0 0; true, because q is true. 23. An equilateral triangle has three congruent sides and an obtuse angle measures greater than 90° and less than 180°; true, because q is true and s is true. 24. 64 8 and an obtuse angle measures greater than 90° and less than 180°; false, because p is false and s is true. 25. An equilateral triangle has three congruent sides and 0 0; false, because q is true and r is false. 26. 0 0 or 64 8; false, because r is false and p is false. 27. An obtuse angle measures greater than 90° and less than 180° or an equilateral triangle has three congruent sides; true, because s is true and q is true. 28. 64 8 and an equilateral triangle has three congruent side, or an obtuse angle measures greater than 90° and less than 180°; true, because s is true.

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41. The teens that said they listened to none of these types of music are represented by the region outside the Pop, Country, and Rap sets. There are 42 teens that said they listened to none of these types of music. 42. The teens that said they listened to all three types of music are represented by the intersection of three sets. There are 7 teens that said they listened to all three types of music. 43. The teens that said they listened to only pop and rap music are represented by the intersection of the Pop and Rap sets excluding the teens that also listen to country music (hence listen to all three types of music). There are 25 teens that said they listened to only pop and rap music. 44. The teens that said they listened to pop, rap, or country music are represented by the union of the Pop, Rap, and Country sets. There are 175 25 7 34 45 10 62 or 358 teens that said they listened to pop, rap, or country music.

29

Chapter 2

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Chapter 2

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52. b; the relationship between Teams A and C is not known, so statements a and c might not be true. It is known that every member of Team A is also a member of Team B so b is true. 53. Sample answer: Logic can be used to eliminate false choices on a multiple choice test. Answers should include the following. • Math is my favorite subject and drama club is my favorite activity. • See students’ work. 54. A; the marks on A B and B C indicate that B A B C , so AB BC is true. Statement A is the only true statement about ABC. 55. C; let x be the first of the integers. Then x 2 is the second integer. Their sum is 78. x x 2 ¬78 2x 2 ¬78 2x ¬76 x ¬38, x 2 40 The two integers are 38 and 40, the greater of which is 40.

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46. The students that participate in either clubs or sports are represented by the union of the sets. There are 60 20 95 or 175 students that participate in clubs or sports. 47. The students that do not participate in either clubs or sports are the students outside the union of the sets. There are 310 – 175 or 135 students that do not participate in either clubs or sports. 48. false 49. True; Rochester is located on Lake Ontario but Syracuse is not. The statement is a disjunction, so it is true. 50. False; Buffalo is located on Lake Erie, so the negation of the statement is false. 51.

Page 74

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2 d (x x (y2 y1)2 2 1) 2 2 LM (4 ) 2 (5 1) 2 42 2 20 25 2 MN (6 ) 4 (4 5)2 2 2 2 1) ( 5 2 ( NP (7 ) 64 4)2 2 ( 2 65 1 8) 2 PQ (5 ) 78 [4)] (2 2 2 (2) ) (4 20 25 2 [8)] QR (3 ) 57 (2 2 2 (2) 1 5 2 ( LR (3 ) 27 1)2 2 ( 2 1 8) 65 Perimeter LM MN NP PQ QR LR 25 5 65 25 5 65 65 2 65 29.5 145°; 90 145 180 so ABC is obtuse. 55°; 55 90 so DBC is acute. 90°; right The front and back could be as much as 35.5 feet each and the sides could be as much as 75.5 feet each. P 2 2w 2(35.5) 2(75.5) 71 151 222 Michelle should buy 222 feet of fencing. 5a 2b 5(4) 2(3) 20 6 or 14 4cd 2d 4(5)(2) 2(2) 40 4 or 44 4e 3f 4(1) 3(2) 4 (6) or 10 2 3g h 3(8)2 (8) 3(64) (8) 192 (8) or 184

2-3 Page 78

4. Hypothesis: it rains on Monday; Conclusion: I will stay home 5. Hypothesis: x 3 7; Conclusion: x 10 6. Hypothesis: a polygon has six sides; Conclusion: it is a hexagon 7. Sample answer: If a pitcher is a 32-ounce pitcher, then it holds a quart of liquid. 8. Sample answer: If two angles are supplementary, then the sum of the measures of the angles is 180. 9. Sample answer: If an angle is formed by perpendicular lines, then it is a right angle. 10. The hypothesis is true because you drove 70 miles per hour, and the conclusion is true because you received a speeding ticket. Since the promised result is true, the conditional statement is true. 11. The hypothesis is false, and the statement does not say what happens if you drive 65 miles per hour or less. You could still get a speeding ticket if you are driving in a zone where the posted speed limit is less than 65 miles per hour. In this case, we cannot say that the statement is false so the statement is true. 12. The hypothesis is true, but the conclusion is false. Because the result is not what was promised, the conditional statement is false. 13. Converse: If plants grow, then they have water; true. Inverse: If plants do not have water, then they will not grow; true. Contrapositive: If plants do not grow, then they do not have water. False; they may have been killed by overwatering. 14. Conditional in if-then form: If you are flying in an airplane, then you are safer than riding in a car. Converse: If you are safer than riding in a car, then you are flying in an airplane. False; there are other places that are safer than riding in a car. Inverse: If you are not flying in an airplane, then you are not safer than riding in a car. False; there are other places that are safer than riding in a car. Contrapositive: If you are not safer than riding in a car, then you are not flying in an airplane; true. 15. Sample answer: If you are in Colorado, then aspen trees cover high areas of the mountains. If you are in Florida, then cypress trees rise from the swamps. If you are in Vermont, then maple trees are prevalent.

Conditional Statements Check for Understanding

1. Writing a conditional in if-then form is helpful so that the hypothesis and conclusion are easily recognizable. 2. Sample answer: If you eat your peas, then you will have dessert. 3. In the inverse, you negate both the hypothesis and the conclusion of the conditional. In the contrapositive, you negate the hypothesis and the conclusion of the converse.

Pages 78–80 Practice and Apply 16. Hypothesis: 2x 6 10; Conclusion: x 2 17. Hypothesis: you are a teenager; Conclusion: you are at least 13 years old 18. Hypothesis: you have a driver’s license; Conclusion: you are at least 16 years old 19. Hypothesis: three points lie on a line; Conclusion: the points are collinear

31

Chapter 2

20. Hypothesis: a man hasn’t discovered something he will die for; Conclusion: he isn’t fit to live 21. Hypothesis: the measure of an angle is between 0 and 90; Conclusion: the angle is acute 22. Sample answer: If you buy a 1-year fitness plan, then you get a free visit. 23. Sample answer: If you are a math teacher, then you love to solve problems. 24. Sample answer: If I think, then I am. 25. Sample answer: If two angles are adjacent, then they have a common side. 26. Sample answer: If two angles are vertical, then they are congruent. 27. Sample answer: If two triangles are equiangular, then they are equilateral. 28. The hypothesis is true because you are 19 years old, and the conclusion is true because you vote. Since the predicted result is true, the conditional statement is true. 29. The hypothesis is false, and the conclusion is true. The statement doesn’t say what happens if you are younger than 18 years old. It is possible that you vote in a school election. In this case, we cannot say that the statement is false. Thus, the statement is true. 30. The hypothesis is true, and the conclusion is false. Because the result is not what was predicted, the conditional statement is false. 31. The hypothesis is false, and the conclusion is false. The statement doesn’t say what happens if you are younger than 18 years old. In this case, we cannot say that the statement is false. Thus, the statement is true. 32. The hypothesis is true because your sister is 21 years old, and the conslusion is true because she votes. Since the predicted result is true, the conditional statement is true. 33. The hypothesis is true, and the conclusion is false. Because the result is not what was predicted, the conditional statement is false. 34. True; P, Q, and R are collinear, and P is in plane M and Q is in plane N. The line containing P and Q is the intersection of M and N, so the line that is the intersection of these planes is the line through P and Q, and thus R. So P, Q, and R are in M. 35. True; points Q and B lie in plane N, so the line that connects them also lies in plane N. 36. True; Q is on the line through P that is the intersection of planes M and N. The line is in M, so Q is in M. 37. False; P and A lie in plane M and Q and B lie in plane N. M and N are distinct planes, so P, Q, A, and B are not coplanar. 38. false 39. True; line RQ is the same as line PQ since P, Q, and R are collinear. P is in M and Q is in N so M and N intersect at line PQ and hence line RQ. Chapter 2

40. Converse: If you live in Texas, then you live in Dallas. False; you could live in Austin. Inverse: If you don’t live in Dallas, then you don’t live in Texas. False; you could live in Austin. Contrapositive: If you don’t live in Texas, then you don’t live in Dallas; true. 41. Converse: If you are in good shape, then you exercise regularly; true. Inverse: If you do not exercise regularly, then you are not in good shape; true. Contrapositive: If you are not in good shape, then you do not exercise regularly. False; an ill person may exercise a lot, but still not be in good shape. 42. Conditional: If two angles are complementary, then their sum is 90. Converse: If the sum of two angles is 90, then they are complementary; true. Inverse: If two angles are not complementary, then their sum is not 90; true. Contrapositive: If the sum of two angles is not 90, then they are not complementary; true. 43. Conditional: If a figure is a rectangle, then it is a quadrilateral. Converse: If a figure is a quadrilateral, then it is a rectangle. False; it could be a rhombus. Inverse: If a figure is not a rectangle, then it is not a quadrilateral. False; it could be a rhombus. Contrapositive: If a figure is not a quadrilateral, then it is not a rectangle; true. 44. Conditional: If an angle is a right angle, then its measure is 90. Converse: If an angle has a measure of 90, then it is a right angle; true. Inverse: If an angle is not a right angle, then its measure is not 90; true. Contrapositive: If an angle does not have a measure of 90, then it is not a right angle; true. 45. Conditional: If an angle is acute, then its measure is less than 90. Converse: If an angle has measure less than 90, then it is acute; true. Inverse: If an angle is not acute, then its measure is not less than 90; true. Contrapositive: If an angle’s measure is not less than 90, then it is not acute; true. 46. Sample answer: In Alaska, if it is summer, then there are more hours of daylight than darkness. In Alaska, if it is winter, then there are more hours of darkness than daylight. 47. Sample answer: In Alaska, if there are more hours of daylight than darkness, then it is summer. In Alaska, if there are more hours of darkness than daylight, then it is winter. 48. Sample answer: If I am exercising, then I am asleep. If I am exercising, then I am not asleep. 49. Conditional statements can be used to describe how to get a discount, rebate, or refund. Sample answers should include the following. • If you are not 100% satisfied, then return the product for a full refund. • Wearing a seatbelt reduces the risk of injuries.

32

61. PQR is a right angle. P

50. C; The contrapositive of a statement always has the same truth value as the statement. 51. B; let x be the number of girls in class. Then there are 32 x boys in class.

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3x ¬5(32 x) 3x ¬160 5x 8x ¬160 x ¬20 32 x ¬12 Thus, there are 20 girls and 12 boys in class, so there are 20 12 or 8 more girls than boys.

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Page 80 Maintain Your Skills 52. George Washington was the first president of the United States and a hexagon has 5 sides. p q is false because p is true and q is false. 53. A hexagon has five sides or 60 3 18. q r is false because q is false and r is false. 54. George Washington was the first president of the United States or a hexagon has five sides. p q is true because p is true. 55. A hexagon doesn’t have five sides or 60 3 18. q r is true because q is true. 56. George Washington was the first president of the United States and a hexagon doesn’t have five sides. p q is true because p is true and q is true. 57. George Washington was not the first president of the United States and 60 3 18. p r is false because p is false and r is true. 58. AB CD; AD BC D C

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2 d (x x (y2 y1)2 2 1) 2 CD [0 2)] ( [3 (1)]2 2 2 2 4 20 4.5 2 d (x x (y2 y1)2 2 1) 2 JK [1 3)] ( (0 5)2 2 2 4 5) ( 41 6.4 2 d (x x (y2 y1)2 2 1) 2 PQ [2 (3)] [3 ( 1)]2 2 2 5 2) ( 29 5.4 2 d (x x (y2 y1)2 2 1) RS (4 1)2 7)] [3 (2 2 2 (5) 10 125 11.2 Subtract 4 from each side. Multiply each side by 2. Divide each side by 8.

Page 80 Practice Quiz 1 1. False W

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Chapter 2

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Page 84 Check for Understanding 1. Sample answer: a: If it is rainy, the game will be cancelled. b: It is rainy. c: The game will be cancelled. 2. Transitive Property of Equality: a b and b c implies a c. Law of Syllogism. a implies b and b implies c implies a implies c. Each statement establishes a relationship between a and c through their relationships to b. 3. Lakeisha; if you are dizzy, that does not necessarily mean that you are seasick and thus have an upset stomach. 4. Valid; the conditional is true and the hypothesis is true, so the conclusion is true. 5. Invalid; congruent angles do not have to be vertical. 6. no conclusion 7. Let p, q, and r represent the parts of the statement. p: the midpoint divides a segment q: two segments are congruent r: two segments have equal measures The given statements are true, Statement (1): p → q Statement (2): q → r So by the Law of Syllogism p → r. Thus, the midpoint of a segment divides it into two segments with equal measures. 8. p: Molly arrives at school at 7:30 A.M. q: she will get help in math r: she will pass her math test Statement (3) is a valid conclusion by the Law of Syllogism. 9. Invalid; not all angles that are congruent are right angles. 10. A 35-year old female pays $14.35 per month for $30,000 of insurance, and Ann is a 35-year old female, so by the Law of Detachment, Ann pays $14.35 per month. 11. No; Terry could be a man or a woman. She could be 45 and have purchased $30,000 of life insurance.

5. Converse: If two angles have a common vertex, then the angles are adjacent. False; ABD is not adjacent to ABC. A

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Page 81

Reading Mathematics

1. Conditional: If a calculator runs, then it has batteries. Converse: If a calculator has batteries, then it will run. False; a calculator may be solar powered. 2. Conditional: If two lines intersect, then they are not vertical. Converse: If two lines are not vertical, then they intersect. False; two parallel horizontal lines will not intersect. 3. Conditional: If two angles are congruent, then they have the same measure. Converse: If two angles have the same measure, then they are congruent. true 4. Conditional: If 3x 4 20, then x 7. Converse: If x 7, then 3x 4 20. False; 3x 4 17 when x 7. 5. Conditional: If a line is a segment bisector, then it intersects the segment at its midpoint. Converse: If a line intersects a segment at its midpoint, then it is a segment bisector. true

Chapter 2

Deductive Reasoning

Pages 85–87

Practice and Apply

12. invalid; 10 12 22 13. Valid; since 5 and 7 are odd, the Law of Detachment indicates that their sum is even. 14. Valid; since 11 and 23 are odd, the Law of Detachment indicates that their sum is even. 15. Invalid; the sum is even. 16. Valid; A, B, and C are noncollinear, and by definition three noncollinear points determine a plane.

34

• Doctors use what is known to be true about diseases and when symptoms appear, then deduce that the patient has a particular illness. 34. C; if A were true, then Yasahiro would be a professional athlete by I, contradicting II. If B were true, then either Yasahiro is a professional athlete (contradicting II), or Yasahiro gets paid, which, together with III and I, contradicts II. D contradicts III. If C was not true, then II would be contradicted. Therefore C must be true. 35. B; 15% off the $16 meal means the diner’s meal cost (0.85)($16) or $13.60. 20% of $13.60 means the diner left a tip of (0.20)($13.60) or $2.72. Thus, the diner paid a total of $13.60 $2.72 or $16.32.

17. Invalid; E, F, and G are not necessarily noncollinear. 18. Invalid; the hypothesis is false as there are only two points. 19. Valid; the vertices of a triangle are noncollinear, and therefore determine a plane. 20. no conclusion 21. If the measure of an angle is less than 90, then it is not obtuse. 22. If X is the midpoint of Y Z , then Y X X Z . 23. no conclusion 24. p: you are an in-line skater q: you live dangerously r: you like to dance Yes, statement (3) follows from (1) and (2) by the Law of Syllogism. 25. p: the measure of an angle is greater than 90 q: the angle is obtuse Yes, statement (3) follows from (1) and (2) by the Law of Detachment. 26. Invalid; statement (1) is true, but statement (3) does not follow from (2). Not all congruent angles are vertical angles. 27. p: an angle is obtuse q: the angle cannot be acute Yes, statement (3) follows from (1) and (2) by the Law of Detachment. 28. p: you drive safely q: you can avoid accidents Yes, statement (3) follows from (1) and (2) by the Law of Detachment. 29. p: you are a customer q: you are always right r: you are a teenager r → p does not follow from (p → q) (r → q); invalid 30. p: John Steinbeck lived in Monterey q: during the 1940s, one could hear the grating noise of the fish canneries. If John Steinbeck lived in Monterey in 1941, then he could hear the grating noise of the fish canneries. 31. p: Catriona Le May Doan skated her second 500 meters in 37.45 seconds q: She beat the time of monique GarbrechtEnfeldt r: She would win the race By the Law of Syllogism, if Catriona Le May Doan skated her second 500 meters in 37.45 seconds, then she would win the race. 32. Sample answer: Stacey assumed that the conditional statement was true. 33. Sample answer: Doctors and nurses use charts to assist in determining medications and their doses for patients. Answers should include the following. • Doctors need to note a patient’s symptoms to determine which medication to prescribe, then determine how much to prescribe based on weight, age, severity of the illness, and so on.

Page 87


36. If you try Casa Fiesta, then you’re looking for a fast, easy way to add some fun to your family’s menu. 37. They are a fast, easy way to add fun to your family’s menu. 38. No; the conclusion is implied. 39. q r qr

40.

41.

42.

35

T

T

T

T

F

F

F F

T F

F F

p

r

T

T

F

T

T

F

F

F

F

T

T

T

F

F

T

T

p p r

p T

q T

r T

qr T

p (q r) T

T

T

F

T

T

T

F

T

T

T

T

F

F

F

F

F

T

T

T

F

F

T

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T

F

F F

F F

T F

T F

F F

p

q

r

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T

T

T

T

F

T

F

T

T

F

F

F

T

T

F

T

F

F

F

T

F

F

F

q F F T T F F T T

q r F F T F F F T F

p (q r) T T T T F F T F

Chapter 2

43. HDC is a right angle and HDC and HDF are a linear pair so HDF is a right angle. Thus, HDG is complementary to FDG because mHDG mFDG 90 44. Sample answer: KHJ and DHG 45. Sample answer: JHK and DHK 46. Congruent, adjacent, supplementary, linear pair 47. Yes, slashes on the segments indicate that they are congruent. 48. y B

52.

M F

53.

G

r

W

s 54.

Q P

C

H

R

55.

A

A

n B

x O

(AB)2 (AC)2 (BC)2 (AB)2 ¬32 42 25 AB ¬5 49.

M C M , C N B N , AM CM, 56. Sample answer: A CN BN, M is midpoint of A C , N is midpoint of B C . 57. Sample answer: 1 and 2 are complementary, m1 m2 90. 58. Sample answer: 4 and 5 are supplementary, m4 m5 180, 5 and 6 are supplementary, m5 m6 180, 4 6, m4 m6.

y

D

x O

E C (CD)2 (CE)2 (DE)2 (CD)2 62 82 100 CD 10 50.

Page 88 Geometry Activity: Matrix Logic 1.

y

F

(FG)2 (GH)2 (FH)2 (FG)2 62 42 52 FG 52 7.2 51.

Veterinarian’s office

✓

✗

✗

Computer store

✗

✗

✓

Restaurant

✗

✓

✗

2. Apartment Anita Kelli Scott Eric Ava Roberto ✗ ✗ ✗ ✗ ✗ ✓ A

H

G

Nate John Nick

Nate works at the veterinarian’s office, John works at the restaurant, and Nick works at the computer store.

x O

Job

y

N

B

✗

✗

✗

✓

✗

✗

C

✓

✗

✗

✗

✗

✗

D

✗

✗

✗

✗

✓

✗

E

✗

✗

✓

✗

✗

✗

F

✗

✓

✗

✗

✗

✗

Roberto lives in A, Eric lives in B, Anita lives in C, Ava lives in D, Scott lives in E, and Kelli lives in F. x

M

O

P

(MN)2 (MP)2 (NP)2 (MN)2 92 72 130 MN 130 11.4

Chapter 2

36

10. Given: P is the midpoint of QR and ST, and QR ST. Prove: PQ PT

Postulates and Paragraph Proofs

Q

Page 91

T P


1. Deductive reasoning is used to support claims that are made in a proof. 2.

S R Proof: Since P is the midpoint of Q R and S T , QR and PS = PT = 1 ST by the PQ PR 1 2 2 definition of midpoint. We are given Q R S T so QR ST by the definition of congruent segments. 1 By the Multiplication Property, 1 2 QR = 2 ST. So, by substitution, PQ = PT. 11. Explore: There are six students, and each student is connected to five other students with ribbons. Plan: Draw a diagram to illustrate the solution.

3. postulates, theorems, algebraic properties, definitions 4. Explore: There are four points, and each pair is to be connected by a segment. Plan: Draw a diagram to illustrate the solution. A B

A

F

B

C

E D Solve: Let noncollinear points A, B, C, D, E, and F represent the six students. Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the 6 points, 15 segments can be drawn. Examine: In the figure, A B , A C , A D , A E , A F , B C , D B , B E , B F , C D , C E , C F , D E , D F , and E F each represent a ribbon between two students. There are 15 segments, so 15 ribbons are needed. 12. Explore: There are four points, and each pair is to be connected by a segment. Plan: Draw a diagram. A

C D Solve: Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the four points, six segments can be drawn. Examine: The six segments that can be drawn are A B , A C , A D , B C , B D , and C D . 5. Explore: There are six points, and each pair is to be connected by a segment. Plan: Draw a diagram to illustrate the solution B A C F

6. 7. 8. 9.

D E Solve: Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the 6 points, 15 segments can be drawn. Examine: The 15 segments that can be drawn are A B , A C , A D , A E , A F , B C , B D , B E , B F , C D , C E , F C , D E , D F , and E F . Sometimes; if the planes have a common intersection, then their intersection is one line. Definition of collinear Through any three points not on the same line, there is exactly one plane. Through any two points, there is exactly one line.

B C D Solve: Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the four points, six segments can be drawn. Examine: The six segments that can be drawn are A B , A C , A D , B C , B D , and C D .

37

Chapter 2

21. Sometimes; and m could be skew, so they would not lie in the same plane. 22. Postulate 2.1: Through any two points, there is exactly one line. 23. Postulate 2.5: If two points lie in a plane, then the entire line containing those points lies in that plane. 24. Postulate 2.2: Through any three points not on the same line, there is exactly one plane. 25. Postulate 2.5: If two points lie in a plane, then the entire line containing those points lies in the plane. 26. Postulate 2.1: Through any two points, there is exactly one line. 27. Postulate 2.2: Through any three points not on the same line, there is exactly one plane. 28. Given: C is the midpoint of A B . B is the midpoint of C D . Prove: A C B D

13. Explore: There are five points, and each pair is to be connected by a segment. Plan: Draw a diagram. A B

C D E Solve: Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the five points, ten segments can be drawn. Examine: The ten segments that can be drawn are A B, A C, A D, A E, B C, B D, B E, C D, C E, and D E. 14. Explore: There are six points, and each pair is to be connected by a segment. Plan: Draw a diagram. B

A

C F

E D Solve: Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the 6 points, 15 segments can be drawn. Examine: The 15 segments that can be drawn are A B , A C , A D , A E , A F , B C , B D , B E , B F , C D , C E , F C , D E , D F , and E F . 15. Explore: There are seven points, and each pair is to be connected by a segment. Plan: Draw a diagram A B

29.

30.

31. C D

16. 17. 18. 19. 20.

E

F G Solve: Connect each point with every other point. Then, count the number of segments. Between every two points there is exactly one segment. For the 7 points, 21 segments can be drawn. Examine: The 21 segments that can be drawn are A B , A C , A D , A E , A F , A G , B C , B D , B E , B F , B G , D C , C E , C F , C G , D E , D F , D G , E F , E G , and F G . Sometimes; the three points cannot be on the same line. Always; if two points lie in a plane, then the entire line containing those points lies in that plane. Never; the intersection of a line and a plane can be a point, but the intersection of two planes is a line. Sometimes; the three points cannot be on the same line. Always; one plane contains at least three points, so it must contain two.

Chapter 2

32.

33.

38

A C B D Proof: We are given that C is the midpoint of A B , and B is the midpoint of C D . By the definition of midpoint A C C B and C B B D . Using the definition of congruent segments, AC CB, and CB BD. AC BD by the Transitive Property of Equality. Thus, A C B D by the definition of congruent segments. There are 4 points, call them A, B, C, and D. Then there is exactly one line between each pair of points, so there are 6 lines: AB, AC, AD, BC, BD, . The points are noncollinear and and CD noncoplanar, and through any three points not on the same line there is exactly one plane. So there are 4 different planes: plane ABC, plane ACD, plane BCD, and plane ABD. Sample answer: Lawyers make final arguments, which is a speech that uses deductive reasoning, in court cases. It’s possible that all five points lie in one plane. The points are noncollinear, and through any three points not on the same line there is exactly one plane. If the five points are points A, B, C, D, and E, then there are as many as 10 planes defined by these points: plane ABC, plane ABD, plane ABE, plane ACD, plane ACE, plane ADE, plane BCD, plane BCE, plane BDE, and plane CDE. Sample answer: The forms and structures of different types of writing are accepted as true, such as the structure of a poem. Answers should include the following. • The Declaration of Independence, “We hold these truths to be self-evident, ...” • Through any two points, there is exactly one line. C; A is true because Postulate 2.2 states that through any 3 points not on the same line, there is exactly one plane. B is true because Postulate 2.6 states that if 2 lines intersect, then their intersection is one point. D is true by the Midpoint Theorem. C is not true because it contradicts Postulate 2.1 which states that through any two points, there is exactly one line.

44. 3y 57 y 19

34. A; (8x4 2x2 3x 5) (2x4 x3 3x 5) 8x4 2x2 3x 5 2x4 x3 3x 5 6x4 x3 2x2 10

y 6

45. 12 ¬14 y ¬2 6

y ¬12 46. t 3 ¬27 t ¬24 t ¬24 47. 8n 39 ¬41 8n ¬80 n ¬10 48. 6x 33 ¬0 6x ¬33

Page 93 Maintain Your Skills 35. p: one has a part-time job q: one must work 20 hours per week Statement (3) is a valid conclusion by the Law of Detachment. 36. Converse: If you have a computer, then you have access to the Internet at your house. False; you can have a computer and not have access to the Internet. Inverse: If you do not have access to the Internet at your house, then you do not have a computer. False; it is possible to not have access to the Internet and still have a computer. Contrapositive: If you do not have a computer, then you do not have access to the Internet at your house. False; you could have Internet access through your television or wireless phone. 37. Converse: If ABC has an angle measure greater than 90, then ABC is a right triangle. False; the triangle would be obtuse. Inverse: If ABC is not a right triangle, none of its angle measures are greater than 90. False; it could be an obtuse triangle. Contrapositive: If ABC does not have an angle measure greater than 90, ABC is not a right triangle. False; mABC could still be 90 and ABC be a right triangle. 38.

11 x ¬ 2

2-6

Algebraic Proof

Page 97


1. Sample answer: If x 2 and x y 6, then 2 y 6. 2. given and prove statements and two columns, one of statements and one of reasons. 3. hypothesis; conclusion 4. Division Property 5. Multiplication Property 6. Substitution 7. Addition Property 8. Given: 2x 4x 7 11 Prove: x 4 Proof:

Animal Arthropod Butterfly

2 d (x x (y2 y1)2 2 1) 2 DF (4 ) 31 ( 3)2 2 2 1 ( 4) 17 4.1 2 40. d (x x (y2 y1)2 2 1) 2 MN (5 0) ) (5 22 2 2 (5) 3 34 5.8 2 41. d (x x (y2 y1)2 2 1) 2 PQ [1 8)] ( (3 2)2 2 2 9 5) ( 106 10.3 2 42. d (x x (y2 y1)2 2 1) 2 RS [2 5)] ( (1 12)2 2 2 7 11) ( 170 13.0 43. m 17 8 m 25

39.

Statements

Reasons

1. 2x 4x 7 11

1. Given

2. 22x 4x 7 2(11)

2. Mult. Prop.

3. x 8x 14 22

3. Distributive Prop.

4. 9x 14 22

4. Substitution

5. 9x 36

5. Add. Prop.

6. x 4

6. Div. Prop.

9. Given: 5 2 3x 1

Prove: x 6 Proof: Statements a.

?

a. Given

b. 35 2 3 x 3(1)

b.

?

Mult. Prop.

c. 15 2x 3

c.

?

Dist. Prop.

d.

?

e. x 6

39

5 2 3x 1

Reasons

2x 12

d. Subt. Prop. e.

?

Div. Prop.

Chapter 2

3x 5 24. Given: 2 7

10. Given: 25 7( y 3) 5y Prove: 2 y Proof: Statements Reasons

Reasons

3x 5 a. 2 7

a.

1. 25 7( y 3) 5y

1. Given

2. 25 7y 21 5y

2. Dist. Prop.

3. 25 2y 21

3. Substitution

b.

4. 4 2y

4. Subt. Prop.

c. 3x 5 14

c.

?

Substitution

5. 2 y

5. Div. Prop.

d. 3x 9

d.

?

Subt. Prop.

e.

11. Given: Rectangle ABCD, AD 3, AB 10 Prove: AC BD 10

A

3

C

10

?

?

?

3x 5 2 2(7) b. Mult. Prop. 2

x3

e. Div. Prop.

Statements

Proof: Statements

Reasons

1. Rectangle ABCD, AD 3, 1. Given AB 10 2. Draw segments AC and 2. Two points DB. determine a line. 3. ABC and BCD are right triangles. 2 1, 2 3 0

4. Pythag. Thm.

5. AC BD

5. Substitution

Reasons

a.

?

2x 7 1 3x 2

b.

?

3(2x 7) 3 1 3x 2

a. Given

c. 6x 21 x 6 d.

3. Def. of rt.

4. AC 2 1 2 DB 3 0

Given

25. Given: 2x 7 1 3x 2 Prove: x 3 Proof:

B

3

D

?

f.

?

b. Mult. Prop. c.

5x 21 6

?

Dist. Prop.

d. Subt. Prop.

e. 5x 15

e.

x3

?

Add. Prop.

f. Div. Prop.

7 26. Given: 4 1 2a 2 a Prove: a 1 Proof:

12. Given: c2 a2 b2 2 b2 Prove: a c Proof:

Statements

Reasons

7 1. 4 1 2a 2 a

1. Given

Statements

Reasons

1. c2 a2 b2

1. Given

7 2. 2 4 1 2 a 2 2 a

2. Mult. Prop.

2. c2 b2 a2

2. Subt. Prop.

3. 8 a 7 2a

3. Dist. Prop.

4. 1 a 2a

4. Subt. Prop.

5. 1 1a

5. Add. Prop.

6. 1 a

6. Div. Prop.

7. a 1

7. Symmetric Prop.

3.

a2

4.

a 2

c2

b2

2 b2 c

2 b2 5. a c

3. Symmetric Prop. 4. Square Root Prop. 5. Square Root Prop.

13. C; 8 x 12 x ¬4 4 x ¬4 4 or 0

1 3 Prove: y 4

Proof:

Transitive Property Subtraction Property Substitution Substitution Division or Multiplication Property Reflexive Property Distributive Property Substitution Division or Multiplication Property Transitive Property

Chapter 2

27. Given: 2y 3 2 8

Pages 97–99 Practice and Apply 14. 15. 16. 17. 18. 19. 20. 21. 22. 23.

Prove: x 3 Proof: Statements

Statements

Reasons

1. 2y 3 2 8

1. Given

2. 2 2y 3 2 2(8) 2. Mult. Prop.

40

3. 4y 3 16

3. Dist. Prop.

4. 4y 13

4. Subt. Prop.

13 5. y 4

5. Div. Prop.

28. Given: 1 2m 9 Prove: m 18 Proof:

Statements

Reasons

1. 1 2m 9

1. Given

3. Substitution

5. mXCA mYBA

5. Subt. Prop.

Ek W

Prove: f h

3. Substitution

Proof:

2z 1 29. Given: 5 3

Prove: z 6 Proof:

Statements

Reasons

1. Ek hf W

1. Given

2. Ek W hf

2. Subt. Prop.

Statements

Reasons

1. 5 2 3z 1

1. Given

3. h f

2. 3 5 2 3 z 3(1)

2. Mult. Prop.

4. f h

3. 15 2x 3

3. Dist. Prop.

4. 15 2x 15 3 15

4. Subt. Prop.

5. 2x 12

5. Substitution

2 x 1 2 6. 2 2

6. Div. Prop.

7. x 6

7. Substitution

Ek W

30. Given: XZ ZY, XZ 4x 1, and ZY 6x 13 Prove: x 7

Ek W

6x

3. Div. Prop. 4. Symmetric Prop.

33. Given: mACB mDCE Prove: mACB mACG mDCE mECF Proof:

X 4x 1 Z

Statements

Reasons

1. mACB mDCE

1. Given

2. mACB mECF mDCE mACG

2. Def. of vert.

3. mACB mACG 3. Transitive Prop. mDCE mECF Thus, all of the angle measures would be equal.

13

Y

Proof: Statements

34. Sample answer: Michael has a symmetric relationship of first cousin with Chris, Kevin, Diane, Dierdre, and Steven. Diane, Dierdre, and Steven have a symmetric and transitive relationship of sibling. Any direct line from bottom to top has a transitive descendent relationship. 35. See students’ work. 36. Sample answer: Lawyers use evidence and testimony as reasons for justifying statements and actions. All of the evidence and testimony is linked together to prove a lawyer’s case similar to a proof in mathematics. Answers should include the following. • Evidence is used to verify facts from witnesses or materials. • Postulates, theorems, definitions, and properties can be used to justify statements made in mathematics.

Reasons

1. XZ ZY, XZ 4x 1, 1. Given and ZY 6x 13 2. 4x 1 6x 13

2. Substitution

3. 4x 1 4x 6x 13 4x

3. Subt. Prop.

4. 1 2x 13

4. Substitution

5. 1 13 2x 13 13

5. Add. Prop.

6. 14 2x

6. Substitution

14 2 x 7. 2 2

7. Div. Prop.

8. 7 x

8. Substitution

9. x 7

9. Symmetric

31. Given: mACB mABC Prove: mXCA mYBA A Proof: X Statements

4. Substitution

32. Given: Ek hf W

2. Mult. Prop. 2. 2 1 2 m 2(9) 3. m 18

3. mXCA mACB mYBA mABC 4. mXCA mACB mYBA mACB

C

B

Y Reasons

1. mACB mABC

1. Given 2. mXCA mACB 180 2. Def. of supp. mYBA mABC 180

41

Chapter 2

37. B; mP mQ mR ¬180 mQ mQ 2(mQ) ¬180 4(mQ) ¬180 mQ ¬45 mP ¬mQ ¬45 38. B; 4 x y 5 x ¬y 9

3. If two lines intersect, then their intersection is exactly one point. 4. If two points lie in a plane, then the entire line containing those points lies in that plane. 5. Given: 2(n 3) 5 3(n 1) Prove: n 2 Proof:

Page 100 Maintain Your Skills 39. Let the four buildings be named A, B, C, and D. In order to have exactly one sidewalk between each building, there should be 6 sidewalks. If A B is the sidewalk between buildings A and B, then the 6 sidewalks are A B , A C , A D , B C , B D , and C D . 40. Valid; since 24 is divisible by 6, the Law of Detachment says it is divisible by 3. 41. Invalid; 27 6 4.5, which is not an integer. 42. Valid; since 85 is not divisible by 3, the contrapositive of the statement and the Law of Detachment say that 85 is not divisible by 6. 43. Sample answer: If people are happy, then they rarely correct their faults. 44. Sample answer: If you don’t know where you are going, then you will probably end up somewhere else. 45. Sample answer: If a person is a champion, then the person is afraid of losing. 46. Sample answer: If we would have new knowledge, then we must get a whole new world of questions. 47. The measurement is precise to within 1 2 foot. So, 1 a measurement of 13 feet could be 122 feet to 131 2 feet. 48. The measurement is precise to within 0.05 meter. So, a measurement of 5.9 meters could be 5.85 meters to 5.95 meters. 49. The measurement is precise to within 0.5 inch. So, a measurement of 74 inches could be 73.5 inches to 74.5 inches. 50. The measurement is precise to within 0.05 kilometer. So, a measurement of 3.1 kilometers could be 3.05 kilometers to 3.15 kilometers. 51. JL ¬JK KL 25 ¬14 KL 11 ¬KL 52. PS ¬PQ QS 51 ¬23 QS 28 ¬QS 53. WZ ¬WY YZ WZ ¬38 9 WZ ¬47

Reasons

1. 2(n 3) 5 3(n 1)

1. Given

2. 2n 6 5 3n 3

2. Dist. Prop.

3. 2n 1 3n 3

3. Substitution

4. 2n 1 2n 3n 3 2n

4. Subt. Prop.

5. 1 n 3

5. Substitution

6. 1 3 n 3 3

6. Add. Prop.

7. 2 n

7. Substitution

8. n 2

2-7

8. Symmetric Prop.

Proving Segment Relationships

Page 101 Geometry Software Investigation: Adding Segment Measures 1. See students’ work. The sum AB BC should always equal AC. 2. See students’ work. The sum AB BC should always equal AC. 3. See students’ work. The sum AB BC should always equal AC. 4. AB BC AC 5. no

Pages 103–104 Check for Understanding 1. Sample answer: The distance from Cleveland to Chicago is the same as the distance from Cleveland to Chicago. 2. Sample answer: If A B X Y and X Y P Q , then B A P Q . P B A

Y X

Q

3. If A, B, and C are collinear and AB BC AC, then B is between A and C. 4. Reflexive 5. Symmetric 6. Subtraction

Page 100 Practice Quiz 2 1. Invalid; not all real numbers are integers. 2. Through any three points not on the same line, there is exactly one plane.

Chapter 2

Statements

42

7. Given: P Q R S , Q S S T Prove: P S R T

R

10. Given: AB C D Prove: C DA B

S T Q

B A C D

P

Proof:

Proof: Statements a.

? , ? S Q S T

Statements

Reasons

1. A B C D

1. Given

2. AB CD

2. Def. of segs.

Def. of segments

3. CD AB

3. Symmetric Prop.

? Segment Addition Post. d. Addition Property

4. C D A B

4. Def. of segs.

Reasons Q P R S , a. Given

b. PQ RS, QS ST

b.

c. PS PQ QS, RT RS ST d. ? PQ QS RS ST

c.

e.

?

PS RT

11. Since Aberdeen is in South Dakota while Helena, Miles City, and Missoula are in Montana, Aberdeen is at one end of the line segment along which the four cities lie. Miles City is closest to Aberdeen (473 miles), Helena is next closest to Aberdeen (860 miles), and Missoula is farthest from Aberdeen (972 miles). Thus, Helena is between Missoula and Miles City.

e. Substitution

S R T f. P 8. Given: AP C P P B D P Prove: A B C D Proof:

?

f.

?

A C

Statements

Def. of segments P

D B

Pages 104–106 Practice and Apply

Reasons

12. 13. 14. 15. 16. 17. 18.

1. A P C P and B P D P 1. Given 2. AP CP and BP DP 2. Def. of segs. 3. AP PB AB

3. Seg. Add. Post.

4. CP DP AB

4. Substitution

5. CP PD CD

5. Seg. Add. Post.

6. AB CD

6. Transitive Prop.

7. A B C D

7. Def. of segs.

9. Given: HI T U and H J T V Prove: IJ U V

Symmetric Substitution Segment Addition Transitive Addition Subtraction Given: A D C E , D B E B Prove: A B C B

B D

E

H A

I

C

Proof: J

T

U

Statements:

V

a.

Proof:

?

Reasons:

D A C E , D B E B a. Given

Statements

Reasons

b. AD CE, DB EB

b.

?

Def. of segs.

1. H I T U and H J T V

1. Given

2. HI TU and HJ TV

2. Def. of segs.

c. AD DB CE EB

c.

?

Add. Prop.

3. HI IJ HJ

3. Seg. Add. Post.

d. Segment Addition Postulate

4. TU IJ TV

d. ? AB AD DB, CB CE EB

4. Substitution

5. TU UV TV

5. Seg. Add. Post.

e. AB CB

e.

?

Substitution

6. TU IJ TU UV

6. Substitution

f. A B C B

f.

?

Def. of segs.

7. TU TU

7. Reflexive Prop.

8. IJ UV

8. Subt. Prop.

9. IJ U V

9. Def. of segs.

43

Chapter 2

19. Given: X Y W Z and W Z A B Prove: X YA B

W

B A X

Z

Y

Proof: Statements

Reasons

d. WY WA AY, ZX ZA AX

d.

e. WA AY ZA AX

e.

?

Substitution

f. WA WA ZA ZA

f.

?

Substitution

g. 2WA 2ZA

g.

?

Substitution

? WA ZA

1. X Y W Z and W Z A B 1. Given

h.

2. XY WZ and WZ AB 2. Def. of segs.

i. W A Z A

3. XY AB

3. Transitive Prop.

4. X Y A B

4. Def. of segs.

20. Given: A B A C and P C Q B Prove: A P A Q

h. Division Property i.

LM P N 22. Given: and X M X N Prove: L X P X

Def. of segs. P

L N

Statements Q

P

?

M

X

Proof:

B

C

? Segment Addition Post.

Reasons

1. L M P N and X M X N 1. Given

A

2. LM PN and XM XN 2. Def. of segs.

Proof:

3. LM LX XM, PN PX XN

3. Seg. Add. Post.

1. A B A C and P C Q B 1. Given

4. LX XM PX XN

4. Substitution

2. AB AC, PC QB

2. Def. of segs.

5. LX XN PX XN

5. Substitution

3. AB AQ QB, AC AP PC

3. Seg. Add. Post.

6. XN XN

6. Reflexive Prop.

7. LX PX

7. Subt. Prop.

4. AQ QB AP PC

4. Substitution

8. L M P X

8. Def. of segs.

5. AQ QB AP QB

5. Substitution

6. QB QB

6. Reflexive Prop.

7. AP AQ

7. Subt. Prop.

Statements

Reasons

8. A P A Q

8. Def. of segs.

1. AB BC

1. Given

2. AC AB BC

2. Seg. Add. Post.

3. AC BC BC

3. Substitution

4. AC 2BC

4. Substitution

Statements

Reasons

WY Z X 21. Given: A is the midpoint of W Y . A is the midpoint of ZX . Prove: W A Z A Z

W

A

Proof: Statements

X

AB 24. Given: Prove: A BA B Proof:

Y

Reasons

a. W Y Z X a. A is the midpoint of W Y . A is the midpoint of ZX .

?

b. WY ZX

?

c.

23. Given: AB BC Prove: AC 2BC Proof:

b.

Given

Def. of segs.

? WA AY, ZA AX c. Definition of midpoint

Chapter 2

44

A

B

A

C

B

Statements

Reasons

1. A B

1. Given

2. AB AB

2. Reflexive Prop.

3. A B A B

3. Def. of segs.

AQ ¬1 2 AD

25. Given: AB D E C is the midpoint of B D . Prove: A C C E

1 ¬1 2 39 4

A

B

C

D

¬195 8 1 BP ¬2BC 3 ¬1 2 12 4 ¬63 8

E

Proof: Statements

Reasons

1. A B D E , C is the midpoint of B D

1. Given

2. BC CD

2. Def. of midpoint

3 ¬141 4 68

3. AB DE

3. Def. of segs.

¬205 8

4. AB BC CD DE

4. Add. Prop.

5. AB BC AC CD DE CE

5. Seg. Add. Post.

6. AC CE

6. Substitution

7. A C C E

7. Def. of segs.

26. Given: AB E F and C B D E Prove: A C D F

A

AP ¬AB BP

C

AP ¬AQ QP

D

B

E

5 205 8 ¬19 8 QP

1 ¬QP 30. Let x be the price of a box of popcorn. Then a tub of popcorn costs 2x. 60(2x) ¬150 120x ¬150 x ¬1.25 Thus, a box of popcorn costs $1.25 and a tub costs 2(1.25) or $2.50. Total popcorn sales were $275 and $150 of that was for tubs, so boxes account for $275 $150 or 125 $125. So the number of boxes sold was 1.2 5 or 100.

F

Proof: Statements

Reasons

1. A B E F and C B D E

1. Given

Page 106 Maintain Your Skills 31. 32. 33. 34. 35.

2. AB EF and BC DE 2. Def. of segs. 3. AB BC DE EF

3. Add. Prop.

4. AC AB BC, 1DF DE EF

4. Seg. Add. Post.

5. AC DF

5. Substitution

6. A C D F

6. Def. of segs.

36. 37. 38.

N Q O and 27. Sample answers: L M L M N R S S T Q P P O 28. Sample answer: You can use segment addition to find the total distance between two destinations by adding the distances of various points in between. Answers should include the following. • A passenger can add the distance from San Diego to Phoenix and the distance from Phoenix to Dallas to find the distance from San Diego to Dallas. • The Segment Addition Postulate can be useful if you are traveling in a straight line. 29. B; AD ¬AB BC CD

39.

40.

3 1 ¬141 4 12 4 12 4

41.

¬391 4

45

Substitution Distributive Property Addition Property Transitive Property Never; the midpoint of a segment divides it into two congruent segments. Sometimes; if the lines have a common intersection point, then it is a single point. Always; if two planes intersect, they intersect in a line. Sometimes; if the points are noncollinear, then they lie on three distinct lines. P ¬2 2w 44 ¬2(2x 7) 2(x 6) 44 ¬4x 14 2x 12 44 ¬6x 26 18 ¬6x 3 ¬x 2x 7 ¬2(3) 7 or 13 x 6 ¬3 6 or 9 The dimensions of the rectangle are 9 cm by 13 cm. 2x x ¬90 3x ¬90 x ¬30 2x 4x ¬90 6x ¬90 x ¬15

Chapter 2

42. 3x 2 x ¬90 4x 2 ¬90 4x ¬88 x ¬22 43. x 3x ¬180 4x ¬180 x ¬45 44. 26x 10x ¬180 36x ¬180 x ¬5 45. 4x 10 3x 5 ¬180 7x 5 ¬180 7x ¬175 x ¬25

6. Given: 1 and 2 are supplementary, 3 and 4 are supplementary, 1 4 Prove: 2 3

1

Statements

Page 110

Geometry Activity: Right Angles

The lines are perpendicular. They are congruent and they form linear pairs. 90 They form right angles. They all measure 90° and are congruent.

7.

a.

?

Given

?

Def. of supp.

b. m1 m2 180 m3 m4 180

b.

c. m1 m2 m3 m4

c.

? Substitution

d. m1 m4

d.

?

Def. of

e. m2 m3

e.

?

Subt. Prob.

f. 2 3

f.

?

Def. of

VX bisects WVY, Given: VY bisects XVZ. Prove: WVX YVZ

W X

V

Y


1. Tomas; Jacob’s answer left out the part of ABC represented by EBF. 2. Sample Answer: If 1 2 and 2 3, then 1 3. 1

2

Z Proof:

3

3. 1 2 because they are vertical angles. m1 ¬m2 65 ¬m2 4. m6 m8 ¬90 m6 47 ¬90 m6 ¬43 m6 m7 ¬m8 ¬180 43 m7 47 ¬180 m7 90 ¬180 m7 ¬90 5. m11 m12 ¬180 x 4 2x 5 ¬180 3x 9 ¬180 3x ¬189 x ¬63 m11 ¬x 4 ¬63 4 or 59 m12 ¬2x 5 ¬2(63) 5 or 121

Chapter 2

4

Reasons

a. 1 and 2 are supplementary. 3 and 4 are supplementary. 1 4

Proving Angle Relationships

Pages 111–112

3

Proof:

2-8 1. 2. 3. 4. 5.

2

Statements

Reasons

bisects WVY. 1. VX bisects XVZ. VY

1. Given

2. WVX XVY

2. Def. of bisector

3. XVY YVZ

3. Def. of bisector

4. WVX YVZ

4. Trans. Prop.

8. sometimes 9. sometimes 10. Given: Two angles form a linear pair. Prove: The angles are supplementary. 1

2

Paragraph Proof: When two angles form a linear pair, the resulting angle is a straight angle whose measure is 180. By definition, two angles are supplementary if the sum of their measures is 180. By the Angle Addition Postulate, m1 m2 180. Thus, if two angles form a linear pair, then the angles are supplementary.

46

11. Given: ABC is a right angle. Prove: 1 and 2 are complementary angles.

C

B 1

2

A 21. Proof: Statements

Reasons

1. ABC is a right angle.

1. Given

2. mABC 90

2. Def. of rt.

3. mABC m1 m2

3. Angle Add. Post.

4. m1 m2 90 5. 1 and 2 are complementary angles.

4. Substitution 5. Def. of comp.

22.

12. 1 and 2 are complementary to X, so 1 2. m1 ¬m2 2n 2 ¬n 32 2n ¬n 30 n ¬30 13. m1 ¬2n 2 ¬2(30) 2 ¬62 14. m2 n 32 30 32 62 15. mX m1 ¬90 mX 62 ¬90 mX ¬28

Pages 112–114

23.

24.

Practice and Apply

16. m1 m2 ¬180 m1 67 ¬180 m1 ¬113 17. m3 m4 ¬90 38 m4 ¬90 m4 ¬52 18. 7 and 8 are complementary, so m7 m8 90. Also, m5 m6 m7 m8 180, so by substitution m5 m6 90. m6 29, so m5 61. 5 8 so m8 m5 61. Finally, m7 m8 90 so m7 90 61 or 29. 19. m9 m10 ¬180 2x 4 2x 4 ¬180 4x ¬180 x ¬45 m9 ¬2x 4 ¬2(45) 4 or 86 m10 ¬2x 4 ¬2(45) 4 or 94 20. m11 m12 ¬180 4x 2x 6 ¬180 6x 6 ¬180 6x ¬186 x ¬31

25.

m11 4x 4(31) or 124 m12 2x 6 2(31) 6 or 56 13 14 m13 ¬m14 2x 94 ¬7x 49 2x 45 ¬7x 45 ¬5x 9 ¬x m13 2x 94 2(9) 94 or 112 m14 7x 49 7(9) 49 or 112 15 16 m15 ¬m16 x ¬6x 290 5x ¬290 x ¬58 m15 m16 58 17 18 m17 ¬m18 2x 7 ¬x 30 2x ¬x 23 x ¬23 m17 2x 7 2(23) 7 53 m18 x 30 23 30 or 53 m19 m20 ¬180 100 20x 20x ¬180 100 40x ¬180 40x ¬80 x ¬2 m19 100 20x 100 20(2) or 140 m20 20x 20(2) or 40 Given: A Prove: A A A Proof:

47

Statements

Reasons

1. A is an angle.

1. Given

2. mA mA

2. Reflexive Prop.

3. A A

3. Def. of angles

Chapter 2

26. Given: 1 2, 2 3 Prove: 1 3

35. Given: m Prove: 1 2 1

1

2

3

Proof:

27. 28. 29. 30. 31. 32. 33.

m

2 3 4

Proof:

Statements

Reasons

1. 1 2, 2 3

1. Given

2. m1 m2, m2 m3

2. Def. of angles

3. m1 m3

3. Trans. Prop.

4. 1 3

4. Def. of angles

sometimes always always sometimes sometimes always Given: m Prove: 2, 3, 4 are rt.

Statements

Reasons

1. m

1. Given

2. 1 and 2 are rt.

2. lines intersect to form 4 rt. .

3. 1 2

3. All rt. are .

36. Given: 1 2, 1 and 2 are supplementary. Prove: 1 and 2 are rt. . Proof: Statements

1

2 3 4

1 2

Reasons

1. 1 2, 1 and 2 1. Given are supplementary. 2. Def. of supp. 2. m1 m2 180

m

Proof:

3. m1 m2

3. Def. of angle

4. m1 m1 180

4. Substitution

5. 2(m1) 180

5. Add. Prop.

Statements

Reasons

11. m

11. Given

12. 1 is a right angle.

12. Def. of

6. m1 90

6. Div. Prop.

13. m1 90

13. Def. of rt.

7. m2 90

14. 1 4

14. Vert. are

7. Substitution (steps 3, 6)

15. m1 m4 16. m4 90 17. 1 and 2 form a linear pair. 3 and 4 form a linear pair. 18. m1 m2 180, m4 m3 180 19. 90 m2 180, , \90 m3 180

15. Def. of 16. Substitution 17. Def. of linear pair

8. 1 and 2 are rt. .

8. Def. of rt.

19. Substitution

Proof:

10. m2 90, m3 90 11. 2, 3, 4, are rt. .

10. Subt. Prop. 11. Def. of rt. (steps 6, 10)

Statements

Reasons

1. ABD CBD, ABD and CBD form a linear pair.

1. Given

2. ABD and CBD are supplementary.

2. Linear pairs are supplementary.

3. ABD and CBD are rt. .

3. If are and supp., they are rt. .

37. Given: ABD CBD, ABD and CBD form a linear pair Prove: ABD and CBD are rt. . D


34. Given: 1 and 2 are rt. . Prove: 1 2

A

1 2

Proof: Statements

Reasons

1. 1 and 2 are rt. .

1. Given

2. m1 90, m2 90

2. Def. of rt.

3. m1 m 2

3. Substitution

4. 1 2

4. Def. of angles

Chapter 2

48

B

C

38. Given: ABD YXZ Prove: CBD WXZ W X D A Proof:

42. m1 m4 ¬90; m1 m2 m3 m4 ¬180 m1 m1 m4 m4 ¬180 2(m1) 2(m4) ¬180 2(m1 m4) ¬180 m1 m4 ¬90 43. Two angles that are supplementary to the same angle are congruent. Answers should include the following. • 1 and 2 are supplementary; 2 and 3 are supplementary. • 1 and 3 are vertical angles, and are therefore congruent. • If two angles are complementary to the same angle, then the angles are congruent. 44. B; Let x be the measure of one angle. Then the measure of the other angle is 90 x. x 4 90 x ¬1 x ¬4(90 x) x ¬360 4x 5x ¬360 x ¬72 The other angle has mesure 90 72 or 18. 45. B; The members of set T are 1, 4, 9, 16, 25, 36, and 49. The median of these numbers is 16.

Y Z

B

C

Statements

Reasons

1. ABD YXZ, ABD and CBD form a linear pair. YXZ and WXZ form a linear pair.

1. Given; from the figure

2. mABD mCBD 180, mYXZ mWXZ 180


3. mABD mCBD mYXZ mWXZ

3. Substitution

4. mABD mYXZ

4. Def. of

5. mYXZ mCBD mYXZ mWXZ

5. Substitution

6. mYXZ mYXZ

6. Reflexive Prop.

7. mCBD mWXZ

7. Subt. Prop.

Page 114

8. Def. of

46. Given: G is between F and H. H is between G and J. Prove: FG GJ FH HJ

8. CBD WXZ 39. Given: mRSW mTSU Prove: mRST mWSU R

G

F Proof:

T W

S


U

Proof: Statements

Reasons

1. mRSW mTSU 2. mRSW mRST mTSW, mTSU mTSW mWSU 3. mRST mTSW mTSW mWSU 4. mTSW mTSW 5. mRST mWSU

1. Given 2. Angle Addition Postulate

J

H

Statements

Reasons

1. G is between F and H; H is between G and J. 2. FG GJ FJ, FH HJ FJ 3. FJ FH HJ

1. Given 2. Segment Addition Postulate 3. Symmetric Prop.

4. FG GJ FH HJ

4. Transitive Prop.

Y . 47. Given: X is the midpoint of W Prove: WX YZ XZ

3. Substitution 4. Reflexive Prop. 5. Subt. Prop.

W

X

Y

Z

Proof:

40. m1 m2 ¬180 28 m2 ¬180 m2 ¬152 41. Because the lines are perpendicular, the angles formed are right angles. All right angles are congruent. Therefore, 1 is congruent to 2.

Statements

Reasons

1. X is the midpoint of W Y . 1. Given

49

2. WX XY 3. XY YZ XZ

2. Def. of midpoint

4. WX YZ XZ

4. Substitution

3. Segment Addition Postulate

Chapter 2

48. Given: AC BD Prove: AB CD Proof:

A

B

C

14. The sum of the measures of two supplementary angles is 180 and 1 0.; false, because r is true and p is false. 15. 1 0, and in a right triangle with right angle C, a2 b2 c2, or the sum of the measures of two supplementary angles is 180.; false, because q is true and r is true so q r is true but p is false. 16. In a right triangle with right angle C, a2 b2 c2, or 1 0 or the sum of the measures of two supplementary angles is 180.; true, because p is false and r is true so p r is true but q is true. 17. In a right triangle with right angle C, a2 b2 c2 and the sum of the measures of two supplementary angles is 180, and 1 0.; false, because q is true and r is true so q r is true but p is false. 18. Converse: If an angle is obtuse, then it measures 120. False; the measure could be any value between 90 and 180. Inverse: If an angle measure does not equal 120, then it is not obtuse. False; the measure could be any value other than 120 between 90 and 180. Contrapositive: If an angle is not obtuse, then its measure does not equal 120; true. 19. Converse: If a month has 31 days, then it is March. False; July has 31 days. Inverse: If a month is not March, then it does not have 31 days. False; July has 31 days. Contrapositive: If a month does not have 31 days, then it is not March; true. 20. Converse: If a point lies on the y-axis, then its ordered pair has 0 for its x-coordinate; true. Inverse: If an ordered pair does not have 0 for its x-coordinate, then the point does not lie on the y-axis; true. Contrapositive: If a point does not lie on the y-axis, then its ordered pair does not have 0 for its x-coordinate; true. 21. true, because the hypothesis is satisfied and the conclusion follows 22. true, because the hypothesis is not satisfied and we cannot say the statement is false 23. false, because the hypothesis is satisfied yet the conclusion does not follow 24. true, because the hypothesis is not satisfied and we cannot say the statement is false 25. Valid; by definition, adjacent angles have a common vertex. 26. Invalid; vertical angles also have a common vertex. 27. yes; Law of Detachment p: a student attends North High School q: a student has an ID number 28. Invalid; Statements (1) and (2) are true, but (3) does not follow from (1) and (2). 29. yes; Law of Syllogism p: you like pizza with everything q: you like Cardo’s Pizza r: you are a pizza connoisseur

D

Statements

Reasons

1. AC BD

1. Given

2. AB BC AC, BC CD BD


3. BC BC

3. Reflexive Prop.

4. AB BC BC CD 4. Substitution (2 and 3) 5. AB CD 49. 50. 51. 52. 53. 54. 55.

5. Subt. Prop.

ONM, MNR PMQ QMN N or R POQ, QON, NOM, MOP obtuse Sample answer: NR and NP NML, NMP, NMO, RNM, ONM

Chapter 2 Study Guide and Review Page 115 1. 2. 3. 4. 5. 6. 7. 8.

Vocabulary and Concept Check

conjecture truth value compound and hypothesis converse Postulates informal proof

Pages 115–120 Lesson-by-Lesson Review 9. mA mB 180

135

45

A

B

10. Y is the midpoint of X Z . X

Y

Z

11. LMNO is a square. M N

L

O

12. 1 0 and in a right triangle with right angle C, a2 b2 c2.; false, because p is false and q is true. 13. In a right triangle with right angle C, a2 b2 c2 or the sum of the measures of two supplementary angles is 180.; true, because q is true and r is true. Chapter 2

50

45. Given: AC AB, AC 4x 1, AB 6x 13 Prove: x 7

30. Never; the intersection of two lines is a point. 31. Always; if P is the midpoint of X Y , then X P P Y . By definition of congruent segments, XP PY. 32. sometimes; if M, X, and Y are collinear 33. sometimes; if the points are collinear 34. Always; there is exactly one line through Q and R. The line lies in at least one plane. 35. sometimes; if the right angles form a linear pair 36. Always; the Reflexive Property states that 1 1. 37. Never; adjacent angles must share a common side, and vertical angles do not. 38. Given: M is the midpoint of A B and Q is the midpoint of A M . Prove: AQ 1 4 AB

A 4x

AM 1 M , 2 (AB). Since Q is the midpoint of A

39. 40. 41. 42.

13

B

1

C

Proof:

A Q M B Proof: If M is the midpoint of A B , then

6x

1 1 1 AQ 1 2 AM or 2 2 (AB) 4 AB. Distributive Property Division Property Subtraction Property Transitive Property

Statements

Reasons

1. AC AB, AC 4x 1, AB 6x 13

1. Given

2. 4x 1 6x 13

2. Substitution

3. 4x 1 1 6x 13 1

3. Subt. Prop.

4. 4x 6x 14

4. Substitution

5. 4x 6x 6x 14 6x

5. Subt. Prop.

6. 2x 14

6. Substitution

2 x 1 4 7. 2 2

7. Div. Prop.

8. x 7

8. Substitution

46. Given: MN PQ, PQ RS Prove: MN RS M N R

43. Given: 5 2 1 2x Prove: x 6 Proof:

P

Q

S

Proof:

Statements

Reasons

1. 5 2 1 2x

1. Given

Statements

2. 5 2 2 1 2x 2

2. Subt. Prop.

1. MN PQ, PQ RS

Reasons 1. Given

3. 3 1 2x

3. Substitution

2. MN RS

2. Transitive Prop.

4. 2(3) 2 1 2x

4. Mult. Prop.

5. 6 x

5. Substitution

6. x 6

6. Symmetric Prop.

47. 48. 49. 50. 51. 52. 53.

x 10 44. Given: x 1 2

Prove: x 4 Proof: Statements

Reasons

10 x 1. x 1 2

1. Given

10 x 2. 2(x 1) 2 2

3. 2x 2 x 10

Reflexive Property Symmetric Property Addition Property Transitive Property Division or Multiplication Property Addition Property Given: BC EC, CA CD B Prove: BA DE

E C

D 2. Mult. Prop.

A

Proof:

3. Dist. Prop.

Statements

Reasons

4. 2x 2 2 x 10 2 4. Subt. Prop.

1. BC EC, CA CD

1. Given

5. 2x x 12

5. Substitution

2. BC CA EC CA

2. Add. Prop.

6. 2x x x 12 x

6. Subt. Prop.

3. BC CA EC CD

3. Substitution

7. 3x 12

4. Seg. Add. Post.

7. Substitution

3 x 1 2 8. 3 3

8. Div. Prop.

4. BC CA BA EC CD DE 5. BA DE

9. x 4

9. Substitution

51

5. Substitution

Chapter 2

54. Given: AB CD Prove: AC BD A B Proof:

55. 56. 57. 58.

9. 3 2, or 3x 12 when x 4 and an equilateral triangle is also equiangular.; true, because q is true and r is true so q r is true and p is false 10. Hypothesis: you eat an apple a day; Conclusion: the doctor will stay away; If you eat an apple a day, then the doctor will stay away. Converse: If the doctor stays away, then you eat an apple a day. Inverse: If you do not eat an apple a day, then the doctor will not stay away. Contrapositive: If the doctor does not stay away, then you do not eat an apple a day. 11. Hypothesis: a stone is rolling; Conclusion: it gathers no moss; If a stone is rolling, then it gathers no moss. Converse: If a stone gathers no moss, then it is rolling. Inverse: If a stone is not rolling, then it gathers moss. Contrapositive: If a stone gathers moss, then it is not rolling. 12. valid; Law of Detachment p: two lines are perpendicular q: the lines intersect 13. m1 73 95 m1 22 14. m2 180 (m1 73) 180 (22 73) 85 15. m3 m2 85 16. Given: y 4x 9; x 2 Prove: y 17 Proof:

C D

Statements

Reasons

1. AB CD

1. Given

2. BC BC

2. Reflexive Prop.

3. AB BC CD BC 4. AB BC AC CD BC BD 5. AC BD

3. Add. Prop. 4. Seg. Add. Post. 5. Substitution

m6 180 35 or 145 m7 180 157 or 23 m8 180 90 or 90 Given: 1 and 2 form a linear pair. m2 2(m1) Prove: m1 60 Proof: Statements

1

2

Reasons

a. 1 and 2 form a linear a. ? Given pair. b. ? Supplement b. 1 and 2 are Theorem supplementary. c. ? m1 m2 c. Definition of supplementary 180 angles d. m2 2(m1) e. f.

? m1 2(m1) 180 ?

3(m1) 180

3(m1) 18 0 g. 3 3

h. ?

m1 60

d.

?

Given

e. Substitution f. Substitution

Statements

Reasons

g.

1. y 4x 9; x 2

1. Given

2. y 4(2) 9

2. Substitution

3. y 8 9

3. Substitution

4. y 17

4. Substitution

? Division Property

h. Substitution

Chapter 2 Practice Test

17. Given: AM CN, MB ND Prove: AB CD

Page 121 1. Sample answer: Formal is the two-column proof, informal can be paragraph proofs. 2. Sample answer: You can use a counterexample. 3. Sample answer: statements and reasons to justify statements 4. true; Symmetric Prop. 5. false; y 2 6. false; a 4 7. 3 2 and 3x 12 when x 4.; false, because p is false and q is true 8. 3 2 or 3x 12 when x 4.; true, because p is false and q is true

Chapter 2

A

M

B

D N C Proof: We are given that AM CN, MB ND. By the Addition Property, AM MB CN MB. Then by Substitution, AM MB CN ND. Using the Segment Addition Postulate, AB AM MB, and CD CN ND. Then, by Substitution AB CD. 18. Hypothesis: you are a hard-working person; Conclusion: you deserve a great vacation; If you are a hard-working person, then you deserve a great vacation. 19. A

52

14a. Possible lengths and Perimeter of widths where area is rectangle with given 100 sq ft length and width

Chapter 2 Standardized Test Practice Pages 122–123 1. D; 49 0.143 2.646 49 2. C; 2(7) 3 11, so (7, 11) is on the line. 2(4) 3 5, so (4, 5) is on the line. 2(2) 3 7, so (2, 10) is not on the line. 2(5) 3 13, so (5, 13) is on the line. 3. A; a protractor is used to measure angles, not lengths. A calculator is not a measuring tool. A centimeter ruler is more accurate than a yardstick because its unit of measurement (centimeters) is smaller. 4. B; D E E F so DE EF. 8x 3 ¬3x 7 8x ¬3x 10 5x ¬10 x ¬2 5. A; ACF DCF ACD by the Angle Addition Postulate. So mACF mDCF 90 since ACD is a right angle. Then ACF and DCF are complementary angles. 6. C; inductive reasoning uses specific examples to make a conjecture. 7. A 8. A; divide both sides by 3. 9. The shortest distance is the length of the hypotenuse of the right triangle whose legs have lengths 120 yd and 531 3 yd. Use the Pythagorean Theorem to find the length of the hypotenuse. Call this length d.

d2 (120)2 531 3

d2

10. 11. 12. 13.

1 ft by 100 ft

202 ft

2 ft by 50 ft

104 ft

4 ft by 25 ft

58 ft

5 ft by 20 ft

50 ft

10 ft by 10 ft

40 ft

The dimensions that require the least amount of fencing are 10 ft by 10 ft. 14b. Sample answer: Make a list of all possible wholenumber lengths and widths that will form a 100-square-foot area. Then find the perimeter of each rectangle. Choose the length and width combination that has the smallest perimeter. 14c. As the length and width get closer to having the same measure as one another, the amount of fencing required decreases. 15. Given: 1 and 3 are vertical angles. m1 3x 5, m3 2x 8 Prove: m1 14 1

2 4

3

Proof: Statements

Reasons

a. 1 and 3 are vertical angles. m1 3x 5, a. Given m3 2x 8

2

25,600 14,400 9

d ¬17,24 4.4 d ¬131 yd inverse (p → q) (q → r) → (p → r) Martina drank 300 mg of calcium. Segment Addition Postulate Sample answer: Marti can measure a third distance c, the distance between the ends of the two sides, and make sure it satisfies the equation a2 b2 c2.

53

b. 1 3

b. Vert. are

c. m1 m3

c. Def. of

d. 3x 5 2x 8

d. Substitution

e. x 5 8

e. Subt. Prop.

f. x 3

f. Subt. Prop.

g. m1 3(3) 5

g. Substitution

h. m1 14

h. Substitution

Chapter 2

Chapter 3 Parallel and Perpendicular Lines 2. Juanita; Eric has listed interior angles, but they are not alternate interior angles. 3. Sample answer: looking down railroad tracks 4. ABC, JKL, ABK, CDM 5. A B , J K , L M 6. B K , C L , J K , L M , B L , K M 7. q and r, q and t, r and t 8. p and q, p and t, q and t 9. p and r, p and t, r and t 10. p and q, p and r, q and r 11. alternate interior 12. corresponding 13. consecutive interior 14. alternate exterior 15. p; consecutive interior 16. p; alternate exterior 17. q; alternate interior 18. Sample answer: The pillars form parallel lines. 19. Sample answer: The roof and the floor are parallel planes. 20. Sample answer: One of the west pillars and the base on the east side form skew lines. 21. Sample answer: The top of the memorial “cuts” the pillars.

Page 125 Getting Started PQ PR or RS ST TR or TP

1. 2. 3. 4. 5. The arcs in the figure indicate congruent to 4, 6, and 8. 6. The arcs in the figure indicate congruent to 1, 3, and 7. 7. The arcs in the figure indicate congruent to 1, 5, and 7. 8. The arcs in the figure indicate congruent to 2, 4, and 6. 9. y 7x 12 7(3) 12 21 12 9

that 2 is that 5 is that 3 is that 8 is

2

10. y ¬3x 4 2

¬3(8) 4 16

12 4 ¬3 3 3 11. 2x 4y ¬18 2(6) 4y ¬18 12 4y ¬18 4y ¬6 3 y ¬6 4 or 2

3-1

Pages 129–131

Parallel Lines and Transversals

22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47.

Page 126 Geometry Activity: Draw a Rectangular Prism 1. Planes ABC and EFG are parallel because those are the planes given as parallel. Planes BCG and ADH are parallel, as well as planes ABF and DCG because opposite sides of a rectangular prism are parallel the same way opposite sides of a rectangle are parallel. ; plane 2. Plane ABF intersects plane ABC at AB ; plane ADH DCG intersects plane ABC at DC ; plane BCG intersects intersects plane ABC at AD plane ABC at BC. 3. A E , C G , and D H are parallel to B F because planes BCG and ADH are parallel and planes ABF and DCG are parallel.

Pages 128–129 Check for Understanding 1. Sample answer: The bottom and top of a cylinder are contained in parallel planes.

Chapter 3

54

Practice and Apply

DE , P Q , S T ABC, ABQ, PQR, CDS, APU, DET C B , E F , Q R P A , B Q , C R , F U , P U , Q R , R S , T U ABC, AFU, BCR, CDS, EFU, PQR C B , C D , D E , E F , Q R , R S , S T , T U b and c, b and r, r and c a and c, a and r, r and c a and b, a and r, b and r a and b, a and c, b and c corresponding alternate exterior alternate interior corresponding alternate exterior alternate interior consecutive interior consecutive interior p; corresponding p; alternate interior m; alternate exterior ; alternate exterior m; corresponding q; alternate interior ; corresponding m; consecutive interior

48. Skew lines; the planes are flying in different directions and at different altitudes. 49. C G , D H , E I 50. D E , F G , H I, G H , B F , D H , E I 51. No; plane ADE will intersect all the planes if they are extended. 52. Sample answers: parallel bars in gymnastics, parallel port on a computer, parallel events, parallel voices in a choir, latitude parallels on a map 53. Infinite number; consider any line through P in any plane that does not contain . 54. 1 55. Sample answer: Parallel lines and planes are used in architecture to make structures that will be stable. Answers should include the following. • Opposite walls should form parallel planes; the floor may be parallel to the ceiling. • The plane that forms a stairway will not be parallel to some of the walls. 56. A 57. The elements of M are 15, 18, 21, 24, 27, and 30. The elements of P are 16, 20, 24, and 28. The numbers that are in P but not in M are 16, 20, and 28. Select any one of these three numbers.

61. mEFG is less than 90; Law of Detachment p: an angle is acute q: its measure is less than 90 62.

d ¬ (x2 x1)2 (y2 y1)2 AB ¬ [3 ( 1)]2 [4 (8)]2 ¬ 42 12 2 ¬160

63.

¬12.65 d ¬ (x2 x1)2 (y2 y1)2 CD ¬ (2 0)2 (9 1)2

64.

¬ (2)2 82 ¬68 ¬8.25 d ¬ (x2 x1)2 (y2 y1)2 EF ¬[5 ( 3)]2 [4 (12)] 2 ¬ 82 1 62 ¬320

65.

¬17.89 d ¬ (x2 x1)2 (y2 y1)2 GH ¬(9 4 )2 [ 25 (10) ]2 ¬ 52 ( 15)2 ¬250 ¬15.81

66.

d ¬(x x1)2 (y2 y1)2 2

2

1 JK ¬ (3 1)2 7 4 4

Page 131


¬ (4)2 (2)2 ¬20

58. Given: mABC ¬mDFE m1 ¬m4 A Prove: m2 ¬m3 1

B

Proof:

2

3

C

E

1. mABC mDFE m1 m4

1. Given

2. mABC m1 m2 mDFE m3 m4

2. Angle Addition Post.

3. m1 m2 m3 m4 4. m4 m2 m3 m4

3. Substitution Prop.

5. m2 m3

5. Subt. Prop.

X

Q

Y

2

8 LM ¬ [5 (5)]2 2 5 5

F

Reasons

¬4.47 d ¬ (x2 x1)2 (y2 y1)2

4

Statements

59. P

67.

D

¬ 102 (2)2 ¬104 ¬10.20 68. M A

69.

P N

B

T R


S 70. 50, 180 50 or 130 The measures of the angles 71. 90, 180 90 or 90 The measures of the angles 72. x 2x ¬180 3x ¬180 x ¬60 60, 2(60) or 120 The measures of the angles 73. 2y 3y ¬180 5y ¬180 y ¬36 2y ¬2(36) or 72 3y ¬3(36) or 108 The measures of the angles

R

Z

Since P Q Z Y and Q R X Y , PQ ZY and QR XY by the definition of congruent segments. By the Addition Property, PQ QR ZY XY. Using the Segment Addition Postulate, PR PQ QR and XZ XY YZ. By substitution, PR XZ. Because the measures are equal, P R X Z by the definition of congruent segments. 60. no conclusion

55

are 50 and 130. are 90 and 90.

are 60 and 120.

are 72 and 108. Chapter 3

74. x 2x 3x ¬180 6x ¬180 x ¬30 There are two linear pairs in the figure. In one linear pair the angles measure x and 3x 2x 5x, or 30 and 150. In the other pair the angles measure 3x and x 2x 3x, or 90 and 90. 75. 3x 1 2x 6 ¬180 5x 5 ¬180 5x ¬175 x ¬35 3x 1 ¬3(35) 1 ¬104 2x 6 ¬2(35) 6 ¬76 The measures of the angles are 76 and 104.

2. 35 35

3. 1; all other angles can be determined using the Corresponding Angles Postulate, the Alternate Interior Angles Theorem, the Consecutive Interior Angles Theorem, and the Alternate Exterior Angles Theorem. 4. Alternate Interior Angles Theorem 5. 1 ¬3 m1 ¬m3 m1 ¬110 6. 6 ¬3 m6 ¬m3 m6 ¬110 7. 2 and 3 are supplementary. m2 m3 ¬180 m2 110 ¬180 m2 ¬70 8. 10 ¬12 m10 ¬m12 m10 ¬55 9. 13 ¬12 m13 ¬m12 m13 ¬55 10. 15 ¬12 m15 ¬m12 m15 ¬55 11. 8y 2 25y 20 ¬180 33y 18 ¬180 33y ¬198 y ¬6 10x 8y 2 ¬180 10x 8(6) 2 ¬180 10x 50 ¬180 10x ¬130 x ¬13 12. 4x 5 ¬3x 11 4x ¬3x 16 x ¬16 4x 5 3y 1 ¬180 4(16) 5 3y 1 ¬180 60 3y ¬180 3y ¬120 y ¬40 13. 36

Page 132 Geometry Software Investigation: Angles and Parallel Lines 1. The pairs of corresponding angles are AEG and CFE, AEF and CFH, BEG and DFE, BEF and DFH. The pairs of alternate interior angles are AEF and DFE, BEF and CFE. The pairs of alternate exterior angles are AEG and DFH, BEG and CFH. The pairs of consecutive interior angles are AEF and CFE, BEF and DFE. 2. The pairs of corresponding angles in Exercise 1 that have the same measure are AEG and CFE, AEF and CFH, BEG and DFE, BEF and DFH. The pairs of alternate interior angles that have the same measure are AEF and DFE, BEF and CFE. The pairs of alternate exterior angles that have the same measure are AEG and DFH, BEG and CFH. 3. They are supplementary. 4a. If two parallel lines are cut by a transversal, then corresponding angles are congruent. 4b. If two parallel lines are cut by a transversal, then alternate interior angles are congruent. 4c. If two parallel lines are cut by a transversal, then alternate exterior angles are congruent. 4d. If two parallel lines are cut by a transversal, then consecutive interior angles are supplementary. 5. Yes; the angle pairs show the same relationships. 6. See students’ work. 7a. Sample answer: All of the angles measure 90°. 7b. Sample answer: If two parallel lines are cut by a transversal so that it is perpendicular to one of the lines, then the transversal is perpendicular to the other line.

3-2

2 1 3 31

Draw a third line through the vertex of 1 parallel to the two given lines. 2 is congruent to the angle whose measure is labeled 36° by the Alternate Interior Angles Theorem. So m2 36. 3 is congruent to the angle whose measure is labeled 31° by the Alternate Interior Angles

Angles and Parallel Lines

Page 136 Check for Understanding 1. Sometimes; if the transversal is perpendicular to the parallel lines, then 1 and 2 are right angles and are congruent. Chapter 3

56

Theorem. So m3 31. m1 ¬m2 m3 ¬36 31 or 67

27.

28.

Pages 136–138 Practice and Apply 14.

15.

16.

17.

18.

19.

20.

21.

22.

23.

24.

25.

3 ¬9 m3 ¬m9 m3 ¬75 5 ¬9 m5 ¬m9 m5 ¬75 6 and 9 are supplementary. m6 m9 ¬180 m6 75 ¬180 m6 ¬105 7 ¬9 m7 ¬75 7 and 8 are supplementary. m7 m8 ¬180 75 m8 ¬180 m8 ¬105 11 ¬9 m11 ¬m9 m11 ¬75 12 and 9 are supplementary. m12 m9 ¬180 m12 75 ¬180 m12 ¬105 2 and 3 are supplementary. m2 m3 ¬180 m2 43 ¬180 m2 ¬137 7 ¬3 m7 ¬m3 m7 ¬43 10 ¬2 m10 ¬m2 m10 ¬137 11 ¬3 m11 ¬m3 m11 ¬43 13 ¬3 m13 ¬m3 m13 ¬43 16 ¬2 m16 ¬m2 m16 ¬137

29.

30.

31.

32.

33.

5 ¬3 m5 ¬m3 m5 ¬60 2 and 6 are supplementary. m2 m6 ¬180 m4 m5 m6 ¬180 m6 ¬180 (m4 m5) m2 180 (m4 m5) ¬180 m2 ¬m4 m5 5 ¬3 m5 ¬m3 From Exercise 26, m4 ¬m1 50 m2 ¬m1 m3 m2 ¬50 60 m2 ¬110 m6 m4 m5 ¬180 m6 50 60 ¬180 m6 ¬70 7 ¬2 m7 ¬m2 m2 ¬110 (from Exercise 28) So m7 ¬110. 8 is congruent to an angle that forms a linear pair with 3. m8 m3 ¬180 m8 60 ¬180 m8 ¬120 4x 56 ¬180 4x ¬124 x ¬31 3y 11 56 ¬180 3y 45 ¬180 3y ¬135 y ¬45 2x ¬68 x ¬34 68 3x 15 y2 ¬180 68 3(34) 15 y2 ¬180 155 y2 ¬180 y2 ¬25 y ¬5

34. 110 4 2 3

26.

1

37

2 9

4

1

j

7 6

q

3

k

4 ¬9 9 ¬1 4 ¬1 m4 ¬m1 m4 ¬50

Draw a third line through the vertex of 1 parallel to the two given lines. 2 4 by the Alternate Interior Angles Theorem. m4 110 180, so m4 70 and hence m2 70. 3 is congruent to the angle whose measure is labeled 37° by the Alternate Interior Angles Theorem. So m3 ¬37. m1 ¬m2 m3 ¬70 37 or 107

p

8

5

m

n

57

Chapter 3

39. Given: m Prove: 1 ¬8 2 ¬7

35.

p 1

2 3 4

1

5

2

4 90 3

8

m

157

Proof:

Extend the ray that forms the 157° angle in the opposite direction so that the line crosses the left line of the pair of parallel lines. Then m4 90. m5 m4 m2 ¬180 m5 ¬180 m4 m2 m5 ¬180 90 m2 m5 ¬90 m2 2 ¬3 m2 ¬m3 m3 157 ¬180 m3 ¬23 m2 ¬23 m1 m5 ¬180 m1 90 m2 ¬180 m1 90 23 ¬180 m1 67 ¬180 m1 ¬113 36. x ¬90 3y 11 ¬y 19 3y ¬y 30 2y ¬30 y ¬15 3y 11 4z 2 x ¬180 3(15) 11 4z 2 90 ¬180 4z 126 ¬180 4z ¬54 z ¬13.5 37. 7y 4 7x 9 ¬180 7y 7x 5 ¬180 7y 7x ¬175 7y ¬175 7x y ¬1 7 (175 7x) y ¬25 x 2y 5 11x 1 ¬180 2(25 x) 5 11x 1 ¬180 50 2x 5 11x 1 ¬180 54 9x ¬180 9x ¬126 x ¬14 y ¬25 x ¬25 14 or 11 z 7x 9 ¬180 z 7(14) 9 ¬180 z 107 ¬180 z ¬73 38. The angle with measure 40° is congruent to an angle that forms a linear pair with the angle whose measure is x°. So 40 x 180. Then x 140.

Chapter 3

6 7

5

Statements

Reasons

1. m

1. Given

2. 1 ¬5, 2 ¬6

2. Corresponding Angles Postulate

3. 5 ¬8, 6 ¬7

3. Vertical Angles Theorem

4. 1 ¬8, 2 ¬7

4. Transitive Property

40. Given: m n, is a transversal. Prove: 1 and 2 are supplementary; 3 and 4 are supplementary. Proof:

m n

1 3 2 4

Statements

Reasons

1. m n, is a transversal

1. Given

2. 1 and 3 form a linear pair; 2 and 4 form a linear pair.

2. Def. of linear pair

3. 1 and 3 are supplementary; 2 and 4 are supplementary.

3. If two angles form a linear pair, then they are supplementary.

4. 1 ¬4, 2 ¬3

4. Alt. int. ¬

5. 1 and 2 are supplementary; 3 and 4 are supplementary.

5. Substitution

41. Given: m, m n Prove: n 1 2

m

3 4

n

Proof: Since m, we know that 1 2, because perpendicular lines form congruent right angles. Then by the Corresponding Angles Postulate, 1 3 and 2 4. By the definition of congruent angles, m1 m2, m1 m3 and m2 m4. By substitution, m3 m4. Because 3 and 4 form a congruent linear pair, they are right angles. By definition, n. 42. The angle formed by the pipe on the other side of the road is supplementary to the angle that measures 65°. So the angle is 180 65 or 115.

58

43. 2 and 6 are consecutive interior angles for the same transversal, which makes them supplementary because W X Y Z . 4 and 6 are not necessarily supplementary because WZ may not be parallel to XY. 44. Sample answer: Angles and lines are used in art to show depth, and to create realistic objects. Answers should include the following. • Rectangular shapes are made by drawing parallel lines and perpendiculars. • M. C. Escher and Pablo Picasso use lines and angles in their art. 45. C; Let y° be the measure of the third angle of the right triangle in the figure. 160 ¬y 120 40 ¬y x y 90 ¬180 x 40 90 ¬180 x ¬50 46. C; ax ¬bx c ax bx ¬c (a b)x ¬c c x ¬ b a

5.

4 ¬2 m4 ¬m2 m2 m1 ¬180 m2 105 ¬180 m2 ¬75 m4 ¬75

3-3

Slopes of Lines

Page 142 Check for Understanding 1. horizontal; vertical 2. Curtis; Lori added the coordinates instead of finding the difference. 3. horizontal line, vertical line (y y ) (x2 x1) 1 3 ¬ 2 (4) 4 ¬ 2 or 2

2 1 4. m ¬

5. Line goes through P(0, 4) and Q(4, 2). (y y ) (x2 x1) 2 4 ¬ 40 2 1 ¬ 4 or 2

2 1 m ¬

Page 138 Maintain Your Skills FG B A , D E , F G , IJ , A E , F J CDH G B , C H , F G , H I m1 124 ¬180 m1 ¬56 52. m2 ¬53 53. Hypothesis: it rains this evening Conclusion: I will mow the lawn tomorrow 54. Hypothesis: you eat a balanced diet Conclusion: it will keep you healthy 47. 48. 49. 50. 51.

6. Line m goes through C(0, 3) and D(3, 1). (y y ) (x2 x1) 1 (3) ¬ 30 2 ¬3

2 1 m ¬

7. Line has slope 1 2 (from Exercise 5). Any line perpendicular to has a slope that is the opposite reciprocal of 1 2 , or 2. 0 13 ¬ 8. slope of GH 11 14

2 7 9 2 55. 8 5 3 or 3

13

13 ¬ 2 5 or 25

6 3 9 56. 2 8 ¬ 6

5 7 ¬ slope of RS 4 (3)

¬3 2

12

11 14 3 57. 23 15 8

¬ 1 or 12

The slopes are not the same, so GH and RS are 15 6 not parallel. The product of the slopes is 25 , so GH and RS are not perpendicular. Therefore, GH and RS are neither parallel nor perpendicular.

8 15 23 8 58. 14 11 3 or 3 36 1 8 59. 2 9 5 ¬ 45 4

¬5

9 (9) 9. slope of GH ¬ 9 15 0 ¬ 6 or 0

Page 138 Practice Quiz 1

1 (1) ¬ slope of RS 3 (4) ¬0 7 or 0 and RS are The slopes are the same so GH parallel.

1. p; alternate exterior 2. ; consecutive interior 3. q; alternate interior 4. 6 1 m6 m1 m6 105

59

Chapter 3

10. Start at (1, 2). Move up 2 units and then move right 1 unit. Draw the line through this point and (1, 2).

Pages 142–144 Practice and Apply (y y ) (x2 x1) 32 1 ¬ 7 0 or 7 (y2 y1) 16. m ¬ (x2 x1) 5 (3) ¬ 6 (2) 1 2 ¬ 4 or 2 (y2 y1) 17. m ¬ (x2 x1) 2 3 ¬ 43 5 ¬ 1 or 5 (y2 y1) 18. m ¬ (x2 x1) 2 1 15. m ¬

y

P (1, 2) O

x

. 11. Find the slope of MN

(y y ) (x2 x1) 20 ¬ 1 5 2 ¬4 or 1 2 1 Since 22 1, the slope of the line 2 1 m ¬

37 41 ¬4 3

¬

through A(6, 4) is 2. perpendicular to MN Graph the line. Start at (6, 4). Move up 2 units and then move right 1 unit. Draw the line through this point and (6, 4).

1 (2) 19. slope of PQ ¬ 9 (3) 3 1 ¬ 1 2 or 4 6 2 ¬ slope of UV 53

y

8 ¬ 2 or 4

12

1 The product of the slopes is 4(4) or 1. So, PQ is perpendicular to UV. 3 0 ¬ 20. slope of PQ 0 ( 4)

8 4

A(6, 4)

3

O

8

12

¬4

x

6 ( 3) slope of UV ¬ 8 (4) 9

3

¬ 1 2 or 4 is parallel to UV . The slopes are the same, so PQ 1 7 ¬ 21. slope of PQ 2 (10)

12. The hill has an 8% grade, so the road will rise or fall 8 units vertically with every 100 horizontal 8 2 units traveled. So the slope is either 25 100 8 2 or . 100 25

6

1 2

¬ 12 or

2 13. Let (x1, y1) (0, 0) and m . Then y2 120 25 because the biker is 120 meters below her starting position.

10 ¬ slope of UV 64 1

¬2

(y2 y1) m ¬ (x2 x1) 2 0 ¬ x120 25 20 2 20 ¬ x1 25 2

and UV are The slopes are not the same, so PQ 1 not parallel. The product of the slopes is 21 2 1 and UV are not perpendicular. or 4, so PQ and UV are neither parallel nor Therefore, PQ perpendicular. 12 22. slope of PQ ¬ 9) 0 (

x2 ¬1500 2 then x2 1500. So the current If m 25 position of the biker is represented by (1500, 120) or (1500, 120). 14. The distance is the same no matter which coordinates are used for the biker’s current position. d ¬ (x2 x1)2 (y2 y1)2 2 ¬ (1500 0) (1 20 0)2 2 2 ¬1500 (120) ¬ 2,264 ,400 ¬1505 The biker has traveled 1505 meters down the hill.

1

¬9

1 8 ¬ slope of UV 2 (1) 9 ¬ 1 or 9

1 The product of the slopes is 9(9) or 1. So, PQ . is perpendicular to UV 81 ¬ 23. slope of PQ 91 7

¬8

8 1 ¬ slope of UV 2 (6) 7

¬8

is parallel to UV . The slopes are the same, so PQ

Chapter 3

60

0 (4) 24. slope of PQ ¬ 10 5

The line to be graphed is parallel to CD so the line has slope 1. Start at (1, 3). Move down 1 unit and then move right 1 unit. Draw the line through this point and (1, 3).

¬4 5 13 (8) ¬ slope of UV 59 ¬5 4

The slopes are not the same, so PQ and UV are 5 not parallel. The product of the slopes is 4 5 4 or 1, so PQ and UV are not perpendicular. and UV are neither parallel nor Therefore, PQ perpendicular.

y

O

(y2 y1) 25. m ¬ (x2 x1) 1 2 ¬ 0 ( 1) 3 ¬ or 3 1

x

A( 1, 3)

35. Find the slope of GH.

(y y ) (x2 x1) 4 ( 5) ¬ 1 (4) ¬9 5 (y2 y1) 27. m ¬ (x2 x1) 1 5 ¬ 3 (2) 6 ¬ 1 or 6 (y2 y1) 28. m ¬ (x2 x1) 4 (4) ¬ 4 ( 2) or 0 ¬0 6 2 1 26. m ¬

(y y ) (x2 x1) 03 ¬ 3 0 3 ¬ 3 or 1

2 1 m ¬

Since 1(1) 1, the slope of the line through M(4, 1), is 1. perpendicular to GH Start at (4, 1). Move down 1 unit and then move right 1 unit. Draw the line through this point and (4, 1). y

is 6 (from Exercise 27). A line 29. The slope of LM parallel to LM has the same slope as LM, thus has slope 6. 9 30. The slope of PQ is 5 (from Exercise 26). A line has slope that is the opposite perpendicular to PQ 9

M(4, 1) O

x

36. Start at (7, 1). Move up 2 units and then move right 5 units. Draw the line through this point and (7, 1).

5

reciprocal of 5, or 9. is 0 (from Exercise 28). EF is 31. The slope of EF horizontal, so a line perpendicular to EF is vertical and has undefined slope. 32. The slope of AB is 3 (from Exercise 25). A line parallel to AB has the same slope as AB, thus has slope 3. 33. Start at (2, 1). Move down 4 units and then move right 1 unit. Draw the line through this point and (2, 1).

y

O

x

J ( 7, 1)

y

P ( 2, 1) O

x

34. Find the slope of CD. (y y ) (x2 x1) 1 7 ¬ 5 ( 1) 6 ¬ or 1 6

2 1 m¬¬

61

Chapter 3

1

37. Find the slope of KL.

41. Let (x1, y1) (2000, 35.3) and m 3. (y y ) (x2 x1) 1 40.6 35.3 ¬ x2 2000 3

(y y ) (x2 x1) 7 ¬ 212 2 19 ¬0 which is undefined

2 1 m ¬

2 1 m ¬

x2 2000 ¬3(5.3) x2 ¬2015.9 The median age will be 40.6 in 2016.

KL is a vertical line, so a line parallel to KL through Q(2, 4) is also vertical. Draw a vertical line through (2, 4).

42.

y

O

(y y ) (x2 x1) 3 2 1 7 ¬ x 6 3 3 7 ¬ x 6

2 1 m ¬

7 ¬x 6 13 ¬x

x

12

y

Q( 2, 4) 8

38. Find the slope of DE.

4

(y y ) (x2 x1) 0 2 ¬ 50 2 ¬ 5 2 5 Since 5 2 1, the slope of the line perpendicular to DE through W(6, 4) is 5 2.

(6, 2)

2 1 m ¬

x O

8 (13, 1)

4

(y y ) (x2 x1) 18 ¬ 2 4 9 ¬2 9229 1, so the line containing (x, 2) and

2 1 43. m1 ¬

Start at (6, 4). Move up 5 units and then move right 2 units. Draw the line through this point and (6, 4). 4

4

y

W (6, 4)

(4, 5) perpendicular to the line containing (4, 8) 2

4

4

and (2, 1) has slope 9. (y2 y1) m2 ¬

8

52 9 ¬ 4 x

O

8

x

(x2 x1)

2

2

3

9 ¬ 4 x

12

2(4 x) ¬27 8 2x ¬27 2x ¬19

39. Sample answer: The median age in 1970 is approximately 28. The median age in 2000 is 35.3. Find the slope of the line through (1970, 28) and (2000, 35.3).

1 9 x ¬ 2 y

(y y ) (x2 x1) 35.3 28 ¬ 2000 1970 7.3 ¬ 30

2 1 m ¬

(1–9–, 2)

4

( 4, 5)

¬0.24 The annual rate of change is approximately 0.24 year per year. 40. Sample answer: Let (x1, y1) (2000, 35.3) and m 0.24.

2

O

4

4 8 (2, 1)

4

x

(y y ) (x2 x1) 77 51 ¬ 2000 1998 2 6 ¬ or 13 2

2 1 44. m ¬

(y2 y1) m ¬ (x2 x1) y2 35.3 0.24 ¬ 2010 2000 y2 35.3 0.24 ¬ 10

The percent changes at a rate of 13% per year. (y y )

2 1 45. m ¬ (x x )

2.4 ¬y2 35.3 37.7 ¬y2 The median age will be 37.7 in 2010. Chapter 3

(4, 8)

8

2

1

77 64 ¬ 2000 1999

¬13

62

90 77

13 ¬ x 20 00


13 (x 2000) ¬13 x 2000 ¬1 x ¬2001 90% of classrooms will have Internet access in 2001. 46. No; the graph can only rise until it reaches 100%. 47. The y-intercept can be found by setting the equation for x equal to zero, solving for t, then using this value in the equation for y. x ¬5 2t 0 ¬5 2t 5 ¬2t 5 2 ¬t y ¬3 t

51.

52.

53.

54.

55.

y ¬3 5 2 11 y ¬2

56.

Find the x-intercept in a similar manner. y ¬3 t 0 ¬3 t 3 ¬t x ¬5 2t x ¬5 2(3) x ¬11 11 So two points on the line are (0, 2) and (11, 0).

57. 58. 59. 60. 61. 62. 63.

(y y ) (x2 x1)

2 1 m ¬

11 0 2

¬ 11 0 11

2 1 ¬ or 2 11

6 ¬1 m6 ¬m1 m6 ¬131 7 is supplementary to 6. m7 m 6 ¬180 m7 131 ¬180 m7 ¬49 4 ¬7 m4 ¬m 7 m4 ¬49 m2 m1 ¬180 m2 131 ¬180 m2 ¬49 m5 m1 ¬180 m5 131 ¬180 m5 ¬49 8 ¬6 6 ¬1 8 ¬1 m8 ¬m1 m8 ¬131 ; alternate exterior ; corresponding p; alternate interior q; consecutive interior m; alternate interior q; corresponding H, I, and J are noncollinear. H I J

The slope-intercept form of the equation of the

64. XZ ZY XY.

1

11 line is y 2x 2 .

48. Sample answer: Slope is used when driving through hills to determine how fast to go. Answers should include the following. • Drivers should be notified of the grade so that they can adjust their speed accordingly. A positive slope indicates that the driver must speed up, while a negative slope indicates that the driver should slow down. • An escalator must be at a steep enough slope to be efficient, but also must be gradual enough to ensure comfort.

X Z Y 65. R, S, and T are collinear. y

x

O

S

(y y ) (x2 x1) 2 1 ¬ 3 (5) 3 ¬2 23 23 1, so the slope of the line

2 1 49. C; m ¬

T

R

66. 67. 68. 69. 70.

acute obtuse right obtuse 2x y ¬7 y ¬2x 7 71. 2x 4y ¬5 4y ¬2x 5 1 y ¬2x 5 4

perpendicular to the line containing (5, 1) and (3, 2) is 2 3.

24 50. A; the winning sailboat completed the race in 9 2 hours, or 23 hours. The second-place boat 2 4 completed the race in 8 hours, or 3 hours. The

72. 5x 2y 4 ¬0 5x 4 ¬2y 5 2x 2 ¬y

difference in times is 1 3 hour, or 20 minutes.

5

y ¬2 x 2

63

Chapter 3

Alternate plan: y ¬0.95x 4.95 ¬0.95(60) 4.95 ¬61.95 He should keep his current plan, based on his average usage.

Equations of Lines

3-4

Pages 147–148 Check for Understanding 1. Sample answer: Use the point-slope form where (x1, y1) (2, 8) and m 2 5. 2. Sample answer: y 2x 3, y x 6 3. Sample answer: y x

Pages 148–149 Practice and Apply 15. y ¬mx b y ¬1 6x 4 16. y ¬mx b y ¬2 3x 8 17. y ¬mx b y ¬5 8x 6 18. y ¬mx b 1 y ¬2 9x 3 19. y ¬mx b y ¬x 3 20. y¬¬mx b 1 y¬¬ x1 12 21. y y1 ¬m(x x1) y 1 ¬2(x 3) 22. y y1 ¬m(x x1) y 7 ¬5(x 4) 23. y y1 ¬m(x x1)

y y

x

O

x

4. y ¬mx b 1 y ¬2x 4 5. y ¬mx b 3 y ¬5x 2 6. y ¬mx b y ¬3x 4 7. y y1 ¬m(x x1) y (1) ¬3 2 (x 4)

y (5) ¬4 5 [x (12)]

y 1 ¬3 2 (x 4)

y 5 ¬4 5 (x 12)

8. y y1 ¬m(x x1) y 5 ¬3(x 7) 9. y y1 ¬m(x x1)

24. y y1 ¬m(x x1) 1 y 11 ¬ 1 6 (x 3) 25. y y1 ¬m(x x1) y 17.12 ¬0.48(x 5) 26. y y1 ¬m(x x1) y 87.5 ¬1.3 (x 10) 27. Find the slope of k using (0, 2) and (1, 1).

y 137.5 ¬1.25(x 20) (y y ) (x2 x1)

2 1 10. m ¬

53

¬ 1) 0 ( ¬2 y ¬2x 5

(y y ) (x2 x1) 1 (2) ¬ 1 0

2 1 m ¬

(y y ) (x2 x1) 32 ¬ 1 0

2 1 11. m ¬

¬3 y ¬mx b y ¬3x 2 28. Find the slope of using (0, 5) and (1, 4).

¬1 y ¬x 2 12. The slope of is 2 (from Exercise 10). The line parallel to that contains (4, 4) also has slope 2. y y1 ¬m(x x1) y 4 ¬2(x 4) y 4 ¬2x 8 y ¬2x 4 13. The total monthly cost of Justin’s current plan is y 39.95. For the other provider, the cost increases $0.95 for each hour of connection so the slope is 0.95. The y-intercept is where 0 hours are used, or $4.95. y ¬mx b y ¬0.95x 4.95 14. Current plan: y 39.95 (no matter how many hours Justin uses)

Chapter 3

(y y ) (x2 x1)

2 1 m ¬

45

¬ 1 0 ¬1 y ¬mx b y ¬x 5 29. Find the slope of m using (2, 0) and (1, 2). (y y ) (x2 x1) 2 0 ¬ 1 2

2 1 m ¬

¬2 y y1 ¬m(x x1) y 0 ¬2(x 2) y ¬2x 4

64

y y1 ¬m(x x1)

30. Find the slope of n using (0, 6) and (8, 5). (y2 y1) m ¬ (x2 x1) 5 6 ¬ 80 1 ¬8

y (3) ¬1 5 [x (5)] 1 y 3 ¬5x 1 y ¬1 5x 4

(y y ) (x2 x1) 0 1 ¬ 05 ¬1 5

2 1 40. m ¬

y ¬mx b

y ¬1 8x 6 31. Since the slope of line is 1 (from Exercise 28), the slope of a line perpendicular to it is 1. y y1 ¬m(x x1) y 6 ¬1[x (1)] y 6 ¬x 1 y ¬x 5 32. Since the slope of line k is 3 (from Exercise 27), the slope of a line parallel to it is 3. y y1 ¬m(x x1) y 0 ¬3(x 7) y ¬3x 21

y ¬mx b y ¬1 5x 1

(y y ) (x2 x1) 4 8 ¬ 6 (6) 12 ¬ which is undefined 0

2 1 41. m ¬

There is no slope-intercept form for this line. An equation for the line is x 6. (y y ) (x2 x1) 5 (1) ¬ 8 (4) 4 ¬ 4 or 1

1 33. Since the slope of line n is 8 (from Exercise 30), 1 the slope of a line parallel to it is 8. y y1 ¬m(x x1)

2 1 42. m ¬

y 0 ¬1 8 (x 0)

y y1¬m(x x1) y (1) ¬1[x (4)] y 1 ¬x 4 y ¬x 3 43. 2x 5y ¬8 5y ¬2x 8 8 y ¬2 5x 5 The slope of the line is 2 5 , so the slope of a line . parallel to it is 2 5

y ¬1 8x

34. Since the slope of line m is 2 (from Exercise 29), the slope of a line perpendicular to it is 1 2. y y1 ¬m(x x1) y (3) ¬1 2 [x (3)] 1 3 y 3 ¬ 2 x 2

9 y ¬1 2x 2

35. y ¬mx b y ¬3x 5 36. y ¬mx b y ¬0 x 6 y ¬6

y y1 ¬m(x x1) y (2) ¬2 5 (x 7) 14 y 2 ¬2 5x 5 24 y ¬2 5x 5

44. 2y 2 ¬7 4 (x 7)

(y y ) (x2 x1) 3 0 ¬ 05 ¬3 5

2 1 37. m ¬

4 9 2y 2 ¬7 4x 4 41 2y ¬7 4x 4 41 y ¬7 8x 8

y ¬mx b

7

The slope of the line is 8, so the slope of a line perpendicular to it is 8 7. y y1 ¬m(x x1) y (3) ¬8 7 [x (2)]

y ¬3 5x 3 (y2 y1) 38. m ¬ (x2 x1) 1 (1) ¬ 2 4

16 y 3 ¬8 7x 7

5 y ¬8 7x 7 45. For each appliance Ann sells she earns $50, so Ann earns 15($50) or $750 plus commission. If the total price of the appliances Ann sells is x dollars, her commission is 0.05x. So, Ann earned y 0.05x 750 dollars in a week in which she sold 15 appliances. 46. 750x 47. The number of gallons of paint in stock decreases at a rate of 750 gallons per day. y 750x 10,800

0

¬ 6 or 0 y y1 ¬m(x x1) y (1) ¬0(x 4) y 1 ¬0 y ¬1 (y y ) (x2 x1) (3) 6 ¬ 10 (5) 3 1 ¬ 15 or 5

2 1 39. m ¬

65

Chapter 3

Gallons of Paint (thousands)

48.

16


14

2 1 56. m ¬

(y y ) (x2 x1) 0 ¬ 4 6 0 3 6 ¬4 or 2 (y2 y1) 57. m ¬ (x2 x1) 1 6 ¬ 88 7 ¬ 0 , which is undefined (y2 y1) 58. m ¬ (x2 x1) 3 3 ¬ 6 6 0 ¬ 12 or 0

12 10 8 6 4 2 0

2

4

6

8 10 12 14 16 Days

49. Find x when y ¬0. y ¬750x 10,800 0 ¬750x 10,800 750x ¬10,800 x ¬14 The store will run out of paint after 14 days, so the manager should order more paint after 14 4 or 10 days. 50. Two points on the line are (120, 60) and (130, 70).

59.

60.

(y y ) (x2 x1)

2 1 m ¬

61.

70 (60) ¬ 130 120

51.

52. 53.

54.

62.

0 1 ¬ 10 or 1 y y1 ¬m(x x1) y (60) ¬1(x 120) y 60 ¬x 120 y ¬x 60 The slope of the Jeff Davis/Reeves County line is 1 (from Exercise 50), so the slope of the Reeves/Pecos County line is 1. y y1 ¬m(x x1) y (60) ¬1(x 120) y 60 ¬x 120 y ¬x 180 The equation y mx is the special case of y m(x x1) y1 when x1 y1 0. Sample answer: In the equation of a line, the b value indicates the fixed rate, while the mx value indicates charges based on usage. Answers should include the following. • The fee for air time can be considered the slope of the equation. • We can find where the equations intersect to see where the plans would be equal. A; 2x 8y ¬16 8y ¬2x 16 1

63.

64.

65.

66.

55. B; y2 1, so y 1 and y 1, thus y 1 and y 1.

F

Reasons 1. Given

2. AC AB BC DF DE EF


3. AB BC DE EF

3. Substitution Property 4. Subtraction Property

d ¬(x x1)2 (y2 y1)2 2 AB ¬ (2 10)2 [8 (6)]2 ¬ (12)2 ( 2)2 ¬ 148 BC ¬ [5 (2)]2 [ 7 (8)] 2 2 2 ¬ (3) 1 ¬ 10

66

C

Statements 1. AC ¬DF AB ¬DE

4. BC EF

1 y ¬x 16 4

4(4) ¬1

Chapter 3

7 ¬1 m7 ¬m1 m7 ¬58 5 ¬2 m5 ¬m2 m5 ¬47 m1 m2 m6 ¬180 58 47 m6 ¬180 m6 ¬75 m4 m2 m3 ¬180 m4 47 26 ¬180 m4 ¬107 m8 ¬m2 m3 m8 ¬47 26 m8 ¬73 From Exercise 59, m7 ¬58. From Exercise 63, m8 ¬73. m7 m8 m9 ¬180 58 73 m9 ¬180 m9 ¬49 Given: AC ¬DF A B AB ¬DE Prove: BC ¬EF D E Proof:

67.

68. 69. 70. 71.

6. From Exercise 4, q has slope 1 2 and has y-intercept 2. y ¬mx b

AC ¬ (5 10)2 [7 ( 6)]2 2 2 ¬ (15) ( 1) ¬ 226 AB BC AC ¬ 148 10 226 ¬30.36 2 d ¬ (x2 x1)2 (y2y 1) 2 AB ¬ [2 ( 3)] (9 2)2 ¬ 52 (11) 2 146 2 BC ¬ (0 2 ) [ 10 ( 9)]2 2 2 ¬ (2) (1 ) 5 AC ¬ [0 ( 3)]2 (1 0 2)2 ¬ 32 (12) 2 153 AB BC AC ¬ 146 5 153 ¬26.69 2 and 5, 3 and 8 1 and 5, 2 and 6, 4 and 8, 3 and 7 1 and 7, 4 and 6 2 and 8, 3 and 5

y ¬1 2x 2

7. From Exercise 5, r has slope 4 5 . A line parallel . to r also has slope 4 5 y y1 ¬m(x x1) y 4 ¬4 5 [x (1)] 4 y 4 ¬4 5x 5 1 6 y ¬4 5x 5 8. From Exercise 3, p has slope 7 2 . A line perpendicular to p has slope 2 7. y ¬mx b y ¬2 7x 0 y ¬2 7x

9. The lines are parallel so they have the same slope: 1 4. y y1 ¬m(x x1)

Page 150 Practice Quiz 2 1) 1 ( 1. slope of AB ¬ 63

y (8) ¬1 4 (x 5)

¬2 3

y 8 ¬1 4 (x 5)

4 ( 2) slope of CD ¬ 2 (2) 3 ¬6 4 or 2

2.

10. The line y 3 is a horizontal line, so a line perpendicular to this line is vertical. An equation of the vertical line through (4, 4) is 0 x 4.

The slopes are not the same, so AB and CD are 3 not parallel. The product of the slopes is 2 3 2 or 1, so AB and CD are not perpendicular. and CD are neither parallel nor Therefore, AB perpendicular. 13 ( 11) ¬ slope of AB

3-5 Proving Lines Parallel Page 154 Check for Understanding

3 (3) 2 4 ¬ 6 or 4 8 (6) slope of CD ¬ 80 2 1 ¬ 8 or 4

1. Sample answer: Use a pair of alternate exterior that are congruent and cut by a transversal; show that a pair of consecutive interior angles are supplementary; show that alternate interior are ; show two lines are to same line; show corresponding are . 2. Sample answer:

The product of the slopes is 41 4 or 1. So AB is perpendicular to CD. 3. Line p contains (0, 4) and (2, 3).

t

(y2 y1) m ¬ (x2 x1) 4) 3 ( 7 ¬ 2 0 ¬ 2

m

4. A line parallel to q has the same slope as q. Line q contains (0, 2) and (2, 3).

3. Sample answer: A basketball court has parallel lines, as does a newspaper. The edges should be equidistant along the entire line. 4. m; corresponding angles 5. m; alternate interior angles 6. p q; consecutive interior angles 7. p q; alternate exterior angles

(y y ) (x2 x1) 3 2 1 ¬ 2 0 ¬ 2

2 1 m ¬

5. Line r contains (1, 1) and (4, 3). (y y ) (x2 x1) 3 (1) 4 ¬ 4 1 ¬5

2 1 m ¬

4554 1, so a line perpendicular to r has slope 5 4.

67

Chapter 3

mADE ¬9x 5 ¬9(11.375) 5 ¬97.375 Verify the angle measure by using the value of x to find mABC. mABC ¬7x 3 ¬7(11.375) 3 ¬82.625 Now mCBD 180 mABC 180 82.625 or 97.375. Since mCBD mADE, CBD ADE and m. 10. Given: 1 2 Prove: m 1

8.

A B (5x 9) C D (14x 9)

E

m

Explore: From the figure, you know that mABC 5x 90 and mADE 14x 9. You also know that ABC and ADE are corresponding angles. Plan: For line to be parallel to line m, the corresponding angles must be congruent. So, mABC mADE. Substitute the given angle measures into this equation and solve for x. Solve: mABC ¬mADE 5x 90 ¬14x 9 90 ¬9x 9 81 ¬9x 9 ¬x Examine: Now use the value of x to find mABC. mABC ¬5x 90 ¬5(9) 90 135 Verify the angle measure by using the value of x to find mADE. That is, 14x 9 14(9) 9 or 135. Since mABC mADE, ABC ADE and m. 9.

3 2

Statements

1. Given

2. 2 3

2. Vertical angles are congruent.

3. 1 3

3. Trans. Prop. of

4. m

4. If corr. are , then lines are . 7 1

5

4 1 ¬ 10 or 8 The slope of CD is 1 8 , and the slope of line AB is 1 . The slopes are not equal, so the lines are not 7

parallel. 12. Yes; sample answer: Pairs of alternate interior angles are congruent.

(7x 3)

B D

Pages 155–157

C

13. 14. 15. 16. 17. 18. 19. 20.

Explore: From the figure, you know that mABC 7x 3 and mADE 9x 5. You also know that ABC and CBD are supplementary, and CBD and ADE are alternate interior angles. Plan: For line to be parallel to line m, the alternate interior angles must be congruent. So, mCBD mADE, where mCBD mABC 180. Thus mCBD 180 mABC, so mADE 180 mABC. Substitute the given angle measures into this equation and solve for x. Solve: mADE ¬180 mABC 9x 5 ¬180 (7x 3) 9x 5 ¬180 7x 3 16x 5 ¬180 3 16x ¬182 x ¬11.375 Examine: Now use the value of x to find mADE.

Chapter 3

1. 1 2

4 2 slope of CD ¬ 6 (4)

A

m

Reasons

2 (3) 1 AB ¬ 11. slope of 0 (7) or 7

E (9x 5)

m

Proof:

21. 22. 23. 24.

68

Practice and Apply

a b; alternate interior none m; corresponding none AE and BF; corresponding AE and BF; corresponding and EG ; alternate interior AC and EG ; supplementary consecutive AC interior and JT ; corresponding HS and JT ; alternate interior HS and PR ; supplementary consecutive KN interior and JT ; 2 lines the same line HS

25. Given: t mt Prove: m

Solve: mABC ¬mDEF 8x 4 ¬9x 11 4 ¬x 11 15 ¬x Examine: Verify the angle measures by using the value of x to find mABC and mDEF. mABC ¬8x 4 ¬8(15) 4 or 124 mDEF ¬9x 11 ¬9(15) 11 or 124 Since mABC mDEF, ABC DEF and m. 28. m

t

1

2

m Proof: Statements

Reasons

1. t, m t

1. Given

2. 1 and 2 are right angles.

2. Definition of perpendicular

3. 1 2

3. All rt. are .

4. m

4. If corr. are , then lines are .

26.

A

A

(9x 4)

D

B

B

(7x 1)

m

C

E

F

D C

E

Explore: From the figure, you know that mABC 7x 1 and DEF is a right angle and hence has measure 90. You also know that ABC and DEF are alternate exterior angles. Plan: For line to be parallel to line m, the alternate exterior angles must be congruent. So, mABC mDEF. Substitute the given angle measures into this equation and solve for x. Solve: mABC ¬mDEF 7x 1 ¬90 7x ¬91 x ¬13 Examine: Verify the angle measure by using the value of x to find mABC. That is, 7x 1 7(13) 1 or 90. Since mABC mDEF, ABC DEF and m. 29. m E A D

140

F Explore: From the figure, you know that mABC 9x 4 and mDEF 140. You also know that ABC and DEF are alternate exterior angles. Plan: For line to be parallel to line m, the alternate exterior angles must be congruent. So, mABC mDEF. Substitute the given angle measures into this equation and solve for x. Solve: mABC ¬mDEF 9x 4 ¬140 9x ¬144 x ¬16 Examine: Verify the angle measure by using the value of x to find mABC. That is, 9x 4 9 (16) 4 or 140. Since mABC mDEF, ABC DEF and m. 27.

(4 5x)

A

(8x 4)

E

B

C

D

B

(9x 11)

F

(7x 100)

C

Explore: From the figure, you know that mABC 4 5x and mECD 7x 100. You also know that ABC and ECD are corresponding angles. Plan: For line to be parallel to line m, the corresponding angles must be congruent. So, mABC mECD. Substitute the given angle measures into this equation and solve for x.

m

Explore: From the figure, you know that mABC 8x 4 and mDEF 9x 11. You also know that ABC and DEF are alternate exterior angles. Plan: For line to be parallel to line m, the alternate exterior angles must be congruent. So, mABC mDEF. Substitute the given angle measures into this equation and solve for x.

69

Chapter 3

Solve: mABC ¬mECD 4 5x ¬7x 100 4 ¬12x 100 96 ¬12x 8 ¬x Examine: Verify the angle measures by using the value of x to find mABC and mECD. mABC ¬4 5x ¬4 5(8) or 44 mECD ¬7x 100 ¬7(8) 100 or 44 Since mABC mECD, ABC ECD and m. 30.

Plan: For line to be parallel to line m, the alternate exterior angles must be congruent. So, mABC mDEF. Substitute the given angle measures into this equation and solve for x. Solve: mABC ¬mDEF 178 3x ¬7x 38 178 ¬10x 38 216 ¬10x 21.6 ¬x Examine: Verify the angle measures by using the value of x to find mABC and mDEF. mABC ¬178 3x ¬178 3(21.6) or 113.2 mDEF ¬7x 38 ¬7(21.6) 38 or 113.2 Since mABC mDEF, ABC DEF and m. 32. Given: 1 and 2 are supplementary. 1 Prove: m 2

A

(14x 9)

B D

m

3 (5x 90)

E

C

Proof:

F

m

Explore: From the figure, you know that mABC 14x 9 and mDEF 5x 90. You also know that ABC and DEF are alternate exterior angles. Plan: For line to be parallel to line m, the alternate exterior angles must be congruent. So, mABC mDEF. Substitute the given angle measures into this equation and solve for x. Solve: mABC ¬mDEF 14x 9 ¬5x 90 9x 9 ¬90 9x ¬81 x ¬9 Examine: Verify the angle measures by using the value of x to find mABC and mDEF. mABC ¬14x 9 ¬14(9) 9 or 135 mDEF ¬5x 90 ¬5(9) 90 or 135 Since mABC mDEF, ABC DEF and m. 31.

A

(178 3x)

B

1. 1 and 2 are supplementary.

1. Given

2. 2 and 3 form a linear pair.

2. Definition of linear pair

3. 2 and 3 are supplementary.

3. Supplement Th.

4. 1 3

4. suppl. to same or are .

5. m

5. If corr. are , then lines are .

4 6 7

C m

(7x 38)

m

Proof: We know that 4 6. Because 6 and 7 are vertical angles they are congruent. By the Transitive Property of Congruence, 4 7. Since 4 and 7 are corresponding angles, and they are congruent, m. 34. Given: 2 1, 1 3 S V 2 1 Prove: S T U V W

Proof:

F

Explore: From the figure, you know that mABC 178 3x and mDEF 7x 38. You also know that ABC and DEF are alternate exterior angles.

Chapter 3

Reasons

33. Given: 4 6 Prove: m

E

D

Statements

70

T

3

Statements

Reasons

1. 2 1, 1 3

1. Given

2. 2 3

2. Trans. Prop.

3. S T U V

3. If alt. int. are , lines are .

U

35. Given: AD C D , 1 2 Prove: B CC D

C

(0.75) 1.5 39. slope of AB ¬ 2 (1)

D 2

0.75 or 0.25 ¬ 3

1

B A Proof: Statements

Reasons

1. A D C D , 1 2

1. Given

2. A D B C

2. If alt. int. are , lines are . 3. Perpendicular Transversal Th.

3. B C C D

40.

41. M K N , 1 2, 3 4 36. Given: J Prove: K M L N J K L 1

2

42.

3 4

M N Proof: Statements

43. 44. Reasons

1. J M K N , 1 2, 3 4

1. Given

2. 1 3

2. If lines are , corr. are .

3. 2 4

3. Substitution 4. If corr. are , lines are .

M L N 4. K

45.

37. Given: RSP PQR, R QRS and PQR are supplementary Prove: P S Q R

S

46. Q

P

Proof:

1.5 1.8 CD ¬ slope of 0 (1 .5) 0 .3 ¬ or 0.2 1.5 No, the lines are not parallel since the slopes are not the same. When he measures the angle that each picket makes with the 2 by 4, he is measuring corresponding angles. When all of the corresponding angles are congruent, the pickets must be parallel. The 10-yard lines will be parallel because they are all perpendicular to the sideline and two or more lines perpendicular to the same line are parallel. Consecutive angles are supplementary; opposite angles are congruent; the sum of the measures of the angles is 360. See students’ work. Sample answer: They should appear to have the same slope. Answers should include the following. • The corresponding angles must be equal in order for the lines to be parallel. • The parking lot spaces have right angles. B; 2 and 3 are supplementary to 1 because they each form a linear pair with 1. 4 is not necessarily supplementary to 1 because 1 and 4 are vertical angles and hence are congruent. 1 5 because m and 1 and 5 are corresponding angles. 7 and 6 are supplementary to 5 because they each form a linear pair with 5, and so by substitution 7 and 6 are supplementary to 1. 8 is not necessarily supplementary to 1 because 8 and 5 are vertical angles, so 8 5 and 8 1. D; let p, n, d, and q represent the numbers of pennies, nickels, dimes, and quarters Kendra has, respectively. Then we are given that p 3n, n d, and d 2q. So we can see that n 2q so p 3(2q) or 6q, and thus all the numbers of coins depend on the number of quarters. Kendra has at least one quarter, so if q 1 then d 2(1) or 2, n 2, and p 6(1) or 6. Then 0.01p 0.05n 0.10d 0.25q 0.01(6) 0.05(2) 0.10(2) 0.25(1) 0.61

Statements

Reasons

1. RSP PQR, QRS and PQR are supplementary

1. Given

2. mRSP mPQR

2. Def. of

3. mQRS mPQR 180

3. Definition of suppl.

4. mQRS mRSP 180 5. QRS and RSP are supplementary.

4. Substitution

Page 157

5. Def. of suppl.

47. y ¬mx b y ¬0.3x 6 48. y y1 ¬m(x x1)

QR 6. PS


y (15) ¬1 3 [x (3)]

6. If cons. int. are suppl., lines are .

y 15 ¬1 3x 1

y ¬1 3 x 14

4 2 1 AB ¬ 38. slope of 4 ( 4) or 4 1 0 1 slope of CD ¬ 4 0 or 4 Yes, the lines are parallel since the slopes are the same.

71

Chapter 3

(y2 y1) (x2 x1) 11 7 ¬ 3 5 4 ¬8 or 1 2

49. m ¬

63. d ¬ (x2 x1)2 (y2 y1)2 ¬ (1 8)2 (2 0)2 2 2 ¬(9) 2 ¬ 85 ¬9.22 64. d ¬ (x2 x1)2 (y2 y1)2

y y1 ¬ m(x x1) y 7 ¬1 2 (x 5) 5 y 7 ¬1 2x 2

¬ [8 (6)]2 [ 2 (4)] 2 2 2 ¬(2) 2 ¬ 8 ¬2.83

1 9 y ¬1 2x 2

1 50. The slope of y 1 2 x 14 is 2 , so a line perpendicular to y 2x 4 has slope 2. y y1 ¬m(x x1) y 1 ¬2(x 4) y 1 ¬2x 8 y ¬2x 9 5 2 3 51. slope of BD ¬ or

Page 158 Graphing Calculator Investigation: Points of Intersection 1. Enter the equations in the Y list and graph in the standard viewing window. KEYSTROKES: Y 2 X, T, , n 10 ENTER 2

40 4 3 (3) ¬ or 0 52. slope of CD 4 (1) 2 (2) 53. slope of AB ¬ 0 ( 4) or 1

X, T, , n 2 ENTER () 1 2

0 2 1 54. slope of EO 0 4 or 2 3) 2 ( 55. slope of DE 44

X, T, , N 4 ZOOM 6 Use the CALC menu to find the points of intersection. Find the intersection of a and t. KEYSTROKES: 2nd [CALC] 5 ENTER

¬5 0 , which is undefined Any line parallel to DE also has undefined slope. 5 56. slope of BD (from Exercise 51) 4 The slope of any line perpendicular to BD is 4 5. 57. p q p and q

T T F F

T F T F

58. p T T F F 59. p

q T F T F

T T F F

T F T F

60.

ENTER ENTER

T F F F

q p or q F T T T F F T T

Lines a and t intersect at (5.6, 1.2). Find the intersection of b and t. KEYSTROKES: 2nd [CALC] 5 ENTER ENTER ENTER

q p p q F F T T

F F T F

p q p q p q T T F F

T F T F

F F T T

F T F T

Lines b and t intersect at (2.4, 2.8). 2. Enter the equations in the Y list and graph in the standard viewing window. KEYSTROKES: Y () X, T, , n 3 ENTER

F F F T

() X, T, , n 5 ENTER

61. A picture frame has right angles, so the angles must be complementary angles. 62. d ¬ (x2 x1)2 (y2 y1)2

ZOOM 6 Use the CALC menu to find the points of intersection.

¬ (7 2 )2 (1 9 7)2 2 2 ¬5 1 2 ¬ 169 or 13

Chapter 3

X, T, , n 6

72

Find the intersection of a and t. KEYSTROKES: 2nd [CALC] 5 ENTER

Find the intersection of a and t. KEYSTROKES: 2nd [CALC] 5 ENTER

ENTER ENTER

ENTER ENTER

Lines a and t intersect at (1.5, 4.5). Find the intersection of b and t. KEYSTROKES: 2nd [CALC] 5

Lines a and t intersect at (2.1, 7.3) Find the intersection of b and t. KEYSTROKES: 2nd [CALC] 5 ENTER ENTER ENTER

ENTER ENTER ENTER

Lines b and t intersect at (3.3, 6.9) 5. Enter the equations in the Y list and graph in the standard viewing window. KEYSTROKES: Y 4 5 X, T, , n 2

Lines b and t intersect at (5.5, 0.5). 3. Enter the equations for a and b in the Y = list. Use the DRAW menu to graph t, since it is a vertical line. KEYSTROKES: Y 6 ENTER 0 ENTER 2nd

ENTER 4 5 X, T, , n 7 ENTER () 5 4

[DRAW] 4 () 2 ENTER Use the TRACE function to find the points of intersection. Find the intersection of a and t. KEYSTROKES: TRACE () 2 ENTER

X, T, , n

ZOOM 6

Use the CALC menu to find the points of intersection. Find the intersection of a and t. KEYSTROKES: 2nd [CALC] 5 ENTER ENTER ENTER

Lines a and t intersect at (2, 6). Find the intersection of b and t. KEYSTROKES: TRACE () 2 ENTER

Lines a and t intersect at (1.0, 1.2). Find the intersection of b and t. KEYSTROKES: 2nd [CALC] 5 ENTER ENTER ENTER

Lines b and t intersect at (2, 0). 4. Enter the equations in the Y list and graph in the standard viewing window. KEYSTROKES: Y () 3 X, T, , n 1 ENTER

Lines b and t intersect at (3.4, 4.3).

() 3 X, T, , n 3 ENTER 1 3

X, T, , n

8 ZOOM 6

Use the CALC menu to find the points of intersection.

73

Chapter 3

6. Enter the equations in the Y list and graph in the decimal viewing window. KEYSTROKES: Y () 1 6 X, T, , n

6.

y

O

2 3 ENTER () 1 6 X, T, , n 5 12 ENTER 6 X, T, , n

Z

2 ZOOM 4

A Y 1. Graph line and point A. Place the compass point at point A. Make the setting wide enough so that when an arc is drawn, it intersects in two places. Label these points X and Y. 2. Put the compass at point X and draw an arc above line . . AZ . The segment constructed 4. Draw AZ from point A(2, 6) perpendicular to line appears to intersect line at (2, 4). Use the Distance Formula to find the distance between point A and . d ¬(x x1)2 (y2 y1)2 2

Use the CALC menu to find the points of intersection. Find the intersection of a and t. KEYSTROKES: 2nd [CALC] 5 ENTER ENTER ENTER

Lines a and t intersect at (0.2, 0.7). Find the intersection of b and t. KEYSTROKES: 2nd [CALC] 5 ENTER

¬ (2 2)2 [4 (6)]2 ¬ (4)2 (2)2 16 4 20 4.47 The distance between A and is about 4.47 units. 7. First, write an equation of a line p perpendicular to the given lines. The slope of p is the opposite

ENTER ENTER

4 reciprocal of 3 4 , or 3 . Use the y-intercept of y 3 4 x 1, (0, 1), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1)

Lines b and t intersect at (0.3, 0.5).

3-6

x

X

y (1) ¬4 3 (x 0)

Perpendiculars and Distance

y 1 ¬4 3x y ¬4 3x 1


Next, use a system of equations to determine the 1 point of intersection of y 3 4 x 8 and p.

1. Construct a perpendicular line between them. 2. Sample answer: You are hiking and need to find the shortest path to a shelter. 3. Sample answer: Measure distances at different parts; compare slopes; measure angles. Finding slopes is the most readily available method. 4. L M

3x 1 ¬4x 1 4 8 3 3x 4x ¬1 1 4 3 8 25 x ¬9 12 8 27 x ¬ 50 27 1 y ¬3 4 50 8 7 y ¬ 2 5

K

N

5.

2 7 7 The point of intersection is 50 , 25 . Then, use the Distance Formula to determine the

C B

27 7 distance between (0, 1) and 50 , 25 . 2 2 d ¬ (x2 x1) (y2 y1)

D

A

7 27 0 (1) 5 50 2

¬

E

2

2

¬.81 ¬0.9

The distance between the lines is 0.9 unit.

Chapter 3

74

1 4. Draw PQ. PQ is perpendicular to y 3 4x 4. Label point R at the intersection of the lines. The segment constructed from P(2, 5) 1 perpendicular to y 3 4 x 4 appears to x 1 at R(1, 1). intersect y 3 4 4 Use the Distance Formula to find the distance 1 between P and y 3 4x 4.

x 3y ¬6 3y ¬x 6 y ¬1 3x 2 x 3y ¬14 3y ¬x 14

8.

1 4 y ¬1 3x 3

d ¬ (x2 x1)2 (y2 y1)2

First, write an equation of a line p perpendicular to the given lines. The slope of p is the opposite reciprocal of 1 3 , or 3. Use the y-intercept of 1 y 3 x 2, (0, 2), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y 2 ¬3(x 0) y 2 ¬3x y ¬3x 2 Next, use a system of equations to determine the 1 4 point of intersection of y 1 3 x 3 and p. 1 1 4 3x 3 ¬3x 2

2 ¬ [2 (1)] (5 1)2 2 42 ¬3

¬25 ¬5 1 The distance between P and y 3 4 x 4 is 5 units. 10. water main connection

14 1 3 x 3x ¬2 3

1 0 20 3 x ¬ 3 x ¬2 y ¬3(2) 2 y ¬4 The point of intersection is (2, 4). Then, use the Distance Formula to determine the distance between (0, 2) and (2, 4).


12.

¬ (2 0)2 (4 2)2 ¬40 ¬2 10 The distance between the lines is 2 10 , or approximately 6.32 units.

13.

y

3– x 4

1– 4

B

D

d ¬ (x2 x1)2 (y2 y1)2

9.

A

C J

L

K R

S

y

P (2, 5)

Q

( 1, 1) O

P

14.

x

W

X

Z 1 1. Graph y 3 4 x 4 and point P. Place the compass at point P. Make the setting wide enough so that when an arc is drawn, it 1 intersects y 3 4 x 4 in two places. Label these points of intersection A and B.

Y

15.

M

G

L

2. Put the compass at point A and draw an arc below the line. 3. Using the same compass setting, put the compass at point B and draw an arc to intersect the one drawn in step 2. Label the point of intersection Q.

H K

J R

16.

S

Q

T

X W

75

U V

Chapter 3

17. Graph line and point P. Construct m perpendicular to through P. Line m appears to intersect line at (4, 0). Use the Distance Formula to find the distance between P and . d ¬ (x2 x1)2 (y2 y1)2 2 2 ¬ (4 4 ) (3 0) ¬ 93 The distance between P and is 3 units.

21. First, write an equation of a line p perpendicular to the lines y 2x 2 and y 2x 3. The slope of p is the opposite reciprocal of 2, or 1 2 . Use the y-intercept of the line y 2x 2, (0, 2), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y 2 ¬1 2 (x 0) y 2 ¬1 2x

y

y ¬1 2x 2

P (4, 3) O

Next, use a system of equations to determine the point of intersection of the line y 2x 3 and p. 2x 3 ¬1 2x 2

x

2x 1 2 x ¬2 3 5 2x ¬5

x ¬2 y ¬2(2) 3 y ¬1 The point of intersection is (2, 1). Then, use the Distance Formula to determine the distance between (0, 2) and (2, 1). d ¬ (x2 x1)2 (y2 y1)2 2 2 ¬ (2 0) (1 2) ¬ (2)2 (1)2 ¬ 5 The distance between the lines is 5 units. 22. First, write an equation of a line p perpendicular to the lines y 4x and y 4x 17. The slope of p is the opposite reciprocal of 4, or 1 4 . Use the y-intercept of the line y 4x, (0, 0), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y 0 ¬1 4 (x 0)

18. Graph line and point P. Construct m perpendicular to through P. Line m appears to intersect line at (1, 3). Use the Distance Formula to find the distance between P and . d ¬ (x2 x1)2 (y2 y1)2 ¬ (4 1)2 (4 3) 2 ¬ (5)2 12 26 The distance between P and is 26 units. y

P

m O

x

y ¬1 4x Next, use a system of equations to determine the point of intersection of the line y 4x 17 and p. 4x 17 ¬1 4x

19. The lines y 3 and y 1 are horizontal lines. The y-axis is perpendicular to these lines. The y-intercept of y 3 is (0, 3). The y-axis intersects the line y 1 at the point (0, 1). Use the Distance Formula to determine the distance between (0, 3) and (0, 1). d (x x1)2 (y2 y1)2 2 ¬ (0 0 )2 [1 (3 )]2 2 2 ¬0 4 ¬ 16 or 4 The distance between the lines is 4 units. 20. The lines x 4 and x 2 are vertical lines. The x-axis is perpendicular to these lines. The line x 4 intersects the x-axis at the point (4, 0). The line x 2 intersects the x-axis at the point (2, 0). Use the Distance Formula to determine the distance between (4, 0) and (2, 0). d ¬ (x2 x1)2 (y2 y1)2 2 ¬ (2 4) (0 0 )2 2 ¬(6) 02 36 or 6 The distance between the lines is 6 units.

Chapter 3

1 7 17 ¬ 4 x 4 ¬x y ¬4(4) 17 y ¬1 The point of intersection is (4, 1). Then, use the Distance Formula to determine the distance between (0, 0) and (4, 1).

d ¬ (x2 x1)2 (y2 y1)2 2 ¬ (1 0) (4 0 )2 ¬ (1)2 (4)2 ¬ 17 The distance between the lines is 17 units.

76

4 3 4 x 5 ¬ 3 x 1

23. 2x y ¬4 y ¬2x 4 y ¬2x 4 First, write an equation of a line p perpendicular to the lines y 2x 3 and y 2x 4. The slope of p is the opposite reciprocal of 2, or 1 2 . Use the y-intercept of the line y 2x 3, (0, 3), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1)

4 3 4 x 3 x ¬1 5 25 12 x ¬6 72 x ¬ 25 72 y ¬3 4 25 5 71 y ¬ 25

72 71 The point of intersection is 25 , 25 . Then, use the Distance Formula to determine the 72 71 distance between (0, 1) and 25 , 25 .

y (3) ¬1 2 (x 0) y 3 ¬1 2x y ¬1 2x 3 Next, use a system of equations to determine the point of intersection of the line y 2x 4 and p.

d ¬ (x2 x1)2 (y2 y1)2

72 71 0 (1) 25 25 7 2 9 6 ¬ 25 25

2

2

2x 4 ¬1 2x 3

2

2x 1 2 x ¬3 4

57 6 2 4 ¬ 25 or 5

5x ¬7 2 1 4 x ¬ 5 1 4 y ¬2 5 4 y ¬8 5

2 4 The distance between the lines is 5 units.

25.

y ( 2, 5)

y

( 2, 4)

1 4 8 The point of intersection is 5 , 5 . Then, use the Distance Formula to determine the 1 4 8 distance between (0, 3) and 5 , 5 .

d

2

¬

O

5

x

¬ (x2 x1)2 (y2 y1)2 14 8 5 0 5 (3) 7 ¬ 5 154 2

¬

2

2

The distance from a line to a point not on the line is the length of the segment perpendicular to the line from the point. From the figure, this distance is 1.

2

24 5 ¬ 25 or 9.8 19 6 49 ¬ 25 25

26.

y y

2x

2 O

The distance between the lines is 9.8 units. 24. 3x 4y ¬20 4y ¬3x 20

x

( 3, 4)

y ¬3 4x 5 First, write an equation of a line p perpendicular 3 to the lines y 3 4 x 1 and y 4 x 5. The 4 slope of p is the opposite reciprocal of 3 4 , or 3 . 3 Use the y-intercept of the line y 4x 1, (0, 1), as one of the endpoints of the perpendicular segment.

( 1, 5)

The perpendicular segment from the point (1, 5) to the line y 2x 2 appears to intersect the line y 2x 2 at (3, 4). Use the Distance Formula to find the distance between (1, 5) and y 2x 2. d ¬ (x2 x1)2 (y2 y1)2 2 ¬ [1 (3)] [ 5 ( 4)]2 2 2 ¬2 ( 1) ¬ 5 The distance between the line y 2x 2 and the point (1, 5) is 5 units.

y y1 ¬m(x x1) y (1) ¬4 3 (x 0) y 1 ¬4 3x y ¬4 3x 1 Next, use a system of equations to determine the point of intersection of the line y 3 4x 5 and p.

77

Chapter 3

27. 2x 3y ¬9 3y ¬2x 9 y ¬2 3x 3

32b.

1

P 2

y

32c. y

2– x 3

Q1

3 (0, 3)

O (2, 0)

Q2

P P

x

32d. The perpendicular segment from the point (2, 0) to the line y 2 3 x 3 appears to intersect the x 3 at (0, 3). Use the Distance line y 2 3 Formula to find the distance between (2, 0) and y 2 3 x 3.

P Q1 Q2

d ¬ (x2 x1)2 (y2 y1)2 ¬ (2 0 )2 (0 3)2

P

32e.

¬ 22 (3) 2

Q1

P

Q2

Q1

P

Q2

¬13 The distance between the line y 2 3 x 3 and the point (2, 0) is 13 units.

28. Given: is equidistant to m. n is equidistant to m. Prove: n

32f.

m n 33. Sample answer: We want new shelves to be parallel so they will line up. Answers should include the following. • After marking several points, a slope can be calculated, which should be the same slope as the original brace. • Building walls requires parallel lines.

Paragraph proof: We are given that is equidistant to m, and n is equidistant to m. By definition of equidistant, is parallel to m, and n is parallel to m. By definition of parallel lines, slope of slope of m, and slope of n slope of m. By substitution, slope of slope of n. Then, by definition of parallel lines, n. 29. It is everywhere equidistant from the ceiling. 30. The plumb line will be vertical and will be perpendicular to the floor. The shortest distance from a point to the floor will be along the plumb line. 31. a 3, b 4, c 6, (x1, y1) (4, 6)

34.

C

X

|ax1 by1 c| |3(4) 4(6) 6| ¬ 32 42 a2 b2 |30| ¬ 25

B D AB 16 and X is the midpoint of A B , so XB 8. CD 20 and X is the midpoint of C D , so XD 10. D B A B , so XBD is a right triangle. Use the Pythagorean Theorem to find BD. (XD)2 ¬(XB)2 (BD)2

30 ¬ 5 or 6

32a.

1

P

A

p

102 ¬82 (BD)2

2

36 ¬(BD)2 6 ¬BD

Chapter 3

78

44. Given: NL ¬NM, AL ¬BM Prove: NA ¬NB

35. D; The coin came up heads 14 times, but since the first and last flips were both heads and there were 24 total flips, it’s not possible to have all 14 times heads came up be consecutive. But it is possible that the first 13 flips were heads, or the last 13 flips were heads.

L

M B

A N Proof:


CF ; alternate interior DE DA EF; corresponding DA EF; 1 4 and consecutive interior are supplementary 39. Find the slope of a using (0, 3) and (2, 4).

Statements

Reasons

1. NL NM AL BM

1. Given

2. NL NA AL NM NB BM

2. Segment Addition Post.

2 1 m ¬

3. NA AL NB BM

3. Substitution

4 3 1 ¬ 2 0 or 2 y ¬mx b

4. NA BM NB BM

4. Substitution

5. NA NB

5. Subt. Prop.

36. 37. 38.

(y y ) (x2 x1)

y ¬1 2x 3

Pages 165–166 Geometry Activity: Non-Euclidean Geometry

40. Find the slope of b using (0, 5) and (1, 4).

1. The great circle is finite. 2. A curved path on the great circle passing through two points is the shortest distance between the two points. 3. There exist no parallel lines. 4. Two distinct great circles intersect in exactly two points. 5. A pair of perpendicular great circles divides the sphere into four finite congruent regions. 6. There exist no parallel lines. 7. There are two distances between two points. 8. true 9. False; in spherical geometry, if three points are collinear, any point can be between the other two. 10. False; in spherical geometry, there are no parallel lines.

(y y ) (x2 x1)

2 1 m ¬

4 5 ¬ 1 0 or 1

y ¬mx b y ¬x 5 41. Find the slope of c using (0, 2) and (3, 0). (y y ) (x2 x1) 2) 0 ( 2 ¬ 3 0 or 3

2 1 m ¬

y ¬mx b y ¬2 3x 2

42. Line a has slope 1 2 (from Exercise 39), so a line perpendicular to a has slope 2. y y1 ¬m(x x1) y (4) ¬2[x (1)] y 4 ¬2x 2 y ¬2x 6 43. Line c has slope 2 3 (from Exercise 41), so a line parallel to c has slope 2 3. y y1 ¬m(x x1)

Chapter 3 Study Guide and Review Page 167 1. 2. 3. 4. 5. 6. 7.

y 5 ¬2 3 (x 2) 4 y 5 ¬2 3x 3 11 y ¬2 3x 3


alternate perpendicular parallel transversal alternate exterior congruent consecutive

Pages 167-170 8. 9. 10. 11. 12.

79

Lesson-by-Lesson Review

corresponding alternate exterior consecutive interior corresponding alternate interior Chapter 3

13. 14. 15. 16.

17.

18.

19.

20.

21.

22.

23.

3) 5 ( 25. slope of AB ¬ 41

consecutive interior alternate exterior alternate interior 1 and 2 are supplementary. m1 m2 ¬180 53 m2 ¬180 m2 ¬127 3 ¬6 6 ¬1 3 ¬1 m3 ¬m1 m3 ¬53 m4 m3 ¬180 m4 53 ¬180 m4 ¬127 m5 m6 180 6 ¬1 m6 ¬m1 m5 m1 ¬180 m5 53 ¬180 m5 ¬127 6 ¬1 m6 ¬m1 m6 ¬53 m7 m6 ¬180 m7 53 ¬180 m7 ¬127 Find a. 1 and 2 are supplementary, so m1 m2 180. 3a 40 2a 25 ¬180 5a 65 ¬180 5a ¬115 a ¬23 Find b. 2 4 and m4 m3 180, so m2 m3 180. 2a 25 5b 26 ¬180 2(23) 25 5b 26 ¬180 5b 45 ¬180 5b ¬135 b ¬27 1 1 ¬ slope of AB

¬8 3

1) 2 ( slope of CD ¬ 7 1 ¬3 8 8 The product of the slopes is 8 3 3 or 1. So, AB is perpendicular to CD. 3 0 26. slope of AB ¬ 6 2 ¬3 4

1 (4) slope of CD ¬ 3 (1) ¬3 4

and CD are The slopes are the same, so AB parallel. 27. First, find the slope of AB. (y2 y1) m ¬ (x2 x1) 62 ¬ 1 (1 ) 4 ¬2 or 2

Parallel lines have the same slope, so the slope of the line to be drawn is 2. Graph the line. Start at (2, 3). Move up 2 units and then move right 1 unit. Draw the line through this point and (2, 3). y (2, 3)

O

. 28. First, find the slope of PQ (y y ) (x2 x1) 2 4 ¬ 35 6 ¬ 2 or 3 Since 31 3 1, the slope of the line to be drawn is 1 3 . Graph the line. Start at (2, 2). 2 1 m ¬

3 (4) ¬2 7 9 2 ¬ slope of CD 02 ¬7 2

Move down 1 unit and then move right 3 units. Draw the line through this point and (2, 2). y

The slopes are not the same, so AB and CD are 7 not parallel. The product of the slopes is 2 7 2 or 1, so AB and CD are not perpendicular. and CD are neither parallel nor Therefore, AB perpendicular. 2 2 24. slope of AB ¬ 26

O ( 2, 2)

4 ¬ 4 or 1

29.

2 ( 4) ¬ slope of CD 5 (1) ¬6 6 or 1 and CD are The slopes are the same, so AB parallel.

Chapter 3

x

80

y y1 ¬m(x x1) y (5) ¬2 (x 1) y 5 ¬2x 2 y ¬2x 7

x

(y y ) (x2 x1) 1 5 ¬ 2 2 6 3 ¬ 4 or 2

2 1 30. m ¬

d ¬ (x2 x1)2 (y2 y1)2 ¬ (2 0)2 [3 (4)]2 ¬ (2)2 12 ¬5 The distance between the lines is 5 units.

y y1 ¬m (x x1) y 5 ¬3 2 (x 2) 3 y 5 ¬2x 3 y ¬3 2x 2

42. First, write an equation of a line p perpendicular 1 to y 1 2 x and y 2 x 5. The slope of p is the

opposite reciprocal of 1 2 , or 2. Use the 1 y-intercept of y 2 x, (0, 0), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y 0 ¬2 (x 0) y ¬2x

31. y ¬mx b y ¬2 7x 4 32.

y y1 ¬m(x x1) y (4) ¬3 2 (x 2)

Next, use a system of equations to determine the point of intersection of the line y 1 2 x 5 and p.

y 4 ¬3 2x 3 y ¬3 2x 1

1x 5 ¬2x 2

5 ¬2x 1 2x x 5 ¬5 2 2 ¬x y ¬1 2 (2) 5 y ¬4 The point of intersection is (2, 4). Then, use the Distance Formula to determine the distance between (0, 0) and (2, 4).

33. y ¬mx b y ¬5x 3 (y y ) (x2 x1) 1) ¬ 64 ( 3 7 ¬ 7 or 1

2 1 34. m ¬

35. 36. 37. 38.

y y1 ¬m(x x1) y (1) ¬1(x 3) y 1 ¬x 3 y ¬x 2 AL and BJ, alternate exterior are and BJ , consecutive interior are AL supplementary and GK , 2 lines to the same line CF AL and BJ, alternate interior are

d ¬ (x2 x1)2 (y2 y1)2 ¬ (2 0)2 (4 0)2 ¬ (2)2 42 ¬20 25 The distance between the lines is 20 units.

39. CF and GK, consecutive interior are supplementary 40. CF and GK, corresponding are 41. First, write an equation of a line p perpendicular to y 2x 4 and y 2x 1. The slope of p is the opposite reciprocal of 2, or 1 2 . Use the y-intrecept of y 2x 4, (0, 4), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y (4) ¬1 2 (x 0)

Chapter 3 Practice Test Page 171 1. The slope of a line perpendicular to y 3x 2 7 is . the opposite reciprocal of 3, or 1 3 Sample answer: y 1 3x 1

2. Sample answer: If alternate interior are , then lines are . 3. 2 and 6 each form a linear pair with 1, so 2 and 6 are supplementary to 1. 3 1, so 3 is not necessarily supplementary to 1. m3 m4 m5 180, so m1 m4 m5 180. So 4 and 5 are not supplementary to 1. 4. m8 m12 ¬180 m8 64 ¬180 m8 ¬116 5. 13 ¬12 m13 ¬m12 m13 ¬64 6. 7 ¬12 m7 ¬m12 m7 ¬64

y 4 ¬1 2x

y ¬1 2x 4 Next, use a system of equations to determine the point of intersection of the line y 2x 1 and p. 2x 1 ¬1 2x 4 x ¬4 1 2x 1 2 5x ¬5 2

x ¬2 y ¬2(2) 1 y ¬3 The point of intersection is (2, 3). Then use the Distance Formula to determine the distance between (0, 4) and (2, 3).

81

Chapter 3

1 5 14. slope of FG ¬ 3 3

7. m11 m12 ¬180 m11 64 ¬180 m11 ¬116 8. m3 m4 ¬180 4 ¬12 m4 ¬m12 m3 m12 ¬180 m3 64 ¬180 m3 ¬116 9. 4 ¬12 m4 ¬m12 m4 ¬64 10. m9 m10 180 10 ¬12 m10 ¬m12 m9 m12 ¬180 m9 64 ¬180 m9 ¬116 11.

6 ¬ 6 or 1

Start at (1, 1). Move 1 unit up and then move 1 unit right. Draw the line through this point and (1, 1). y F (3, 5)

O

G

( 3, 1)

x

M(1, 1)

15. Start at (3, 2). Move 4 units up and then move 3 units left. Draw the line through this point and (3, 2).

5 ¬7 7 ¬12 5 ¬12 m5 ¬m12 m5 ¬64

y

O

12. Start at (2, 1). Move 1 unit down and then move 1 unit right. Draw the line through this point and (2, 1).

x

K(3, 2)

y

16. ABD ACE mACE mECF ¬180 mABD mECF ¬180 3x 60 2x 15 ¬180 5x 45 ¬180 5x ¬225 x ¬45 17. DBC ¬ECF mDBC ¬mECF y ¬2(45) 15 y ¬105

( 2, 1) O

x

30 13. slope of AB ¬ 4 (2) 1 ¬3 6 or 2 1 2 (2) 1, so the slope of the line to be graphed is 2. Start at (1, 3). Move 2 units down and then move 1 unit right. Draw the line through this point and (1, 3).

18. mFCF ¬2x 15 ¬2(45) 15 ¬105 19. mABD ¬3x 60 ¬3(45) 60 ¬75 20. mBCE mFCE ¬180 mBCE 105 ¬180 mBCE ¬75

y

B(4, 3) Q ( 1, 3) A( 2, 0) O

Chapter 3

21. mCBD ¬y ¬105

x

82

22. The slope of a line perpendicular to y 2x 1 and y 2x 9 is 1 2 . Use the y-intercept of y 2x 1, (0, 1), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1)

24. The slope of a line perpendicular to y x 4 and y x is 1. Use the y-intercept of y x, (0, 0), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y 0 ¬1(x 0) y ¬x Use a system of equations to determine the point of intersection of the line y x 4 and the perpendicular segment. x 4 ¬x 4 ¬2x 2 ¬x y ¬(2) 4 y ¬2 The point of intersection is (2, 2). Use the Distance Formula to determine the distance between (0, 0) and (2, 2). d ¬ (x2 x1)2 (y2 y1)2 2 ¬ (2 0) (2 0)2 2 2 ¬(2) (2) ¬ 8 ¬2.83 The distance between the lines y x and y x 4 is about 2.83 units. So, the distance between Lorain Road and Detroit Road is about 2.83 miles. 25. B; 1 3, and 3 and 4 are supplementary so 1 and 4 are supplementary. m4 180 m1 so m4 107 and hence m4 73. Furthermore, 1 is not congruent to 4. Lines m and are parallel so consecutive interior angles are supplementary. Hence, m2 m3 180. So the only statement that cannot be true is B.

y (1) ¬1 2 (x 0) y 1 ¬1 2x

y ¬1 2x 1

Use a system of equations to determine the point of intersection of the line y 2x 9 and the perpendicular segment. 2x 9 ¬1 2x 1

2x 1 2 x ¬1 9 5x ¬10 2

x ¬4 y ¬2(4) 9 y ¬1

The point of intersection is (4, 1). Use the Distance Formula to determine the distance between (0, 1) and (4, 1). d ¬ (x2 x1)2 (y2 y1)2 ¬ (4 0)2 [1 (1)] 2 ¬ (4)2 22 ¬20 The distance between the lines is 20 or about 4.47 units. 23. The slope of a line perpendicular to y x 4 and y x 2 is 1. Use the y-intercept of y x 4, (0, 4), as one of the endpoints of the perpendicular segment. y y1 ¬m (x x1) y 4 ¬1(x 0) y 4 ¬x y ¬x 4 Use a system of equations to determine the point of intersection of the line y x 2 and the perpendicular segment. x 2 ¬x 4 2x ¬6 x ¬3 y ¬( 3) 2 y ¬1 The point of intersection is (3, 1). Use the Distance Formula to determine the distance between (0, 4) and (3, 1). d ¬ (x2 x1)2 (y2 y1)2

Chapter 3 Standardized Test Practice Pages 172–173 1. B; 2 m 200 cm 2. C; d ¬(x x1)2 (y2 y1)2 2

3.

4. 5.

¬ (3 0)2 (1 4 )2 2 2 ¬(3) (3) ¬ 18 The distance between the lines is 18 or about 4.24 units.

6. 7.

83

¬ (2 2)2 (3 4)2 ¬(4 )2 (7)2 ¬65 A; statement A is true by definition of angle bisector. There is not enough information to establish that any of the other statements are true. D; 180 72 108 D; 4x 4 ¬6x 8 4 8 ¬6x 4x 12 ¬2x 6 ¬x C B; 1 and 3 are corresponding angles.

Chapter 3

(y y ) (x2 x1) 48 44 ¬ 21

8. C; 4y x ¬8 4y ¬x 8

2 1 15a. m ¬

y ¬1 4x 2

¬4 15b. The slope represents the increase in the average monthly cable bill each year. 15c. The slope of the line through the points is 4. One point on the line is (1, 44). Find the equation of the line. y 44 ¬4(x 1) y 44 ¬4x 4 y ¬4x 40 After 10 years the cable bill will be y 4(10) 40, or $80.

14(4) 1, so the slope of the perpendicular line is 4. y 4x 15 is the only choice with slope 4. 9. C; the number 2 in y 2x 5 is the slope, which determines the steepness of the line. 4x 6 10. 3 3 3(10)

11. mFHC mFHD 180 FHD HGB mFHD mHGB mFHC mHGB ¬180 mFHC 70 ¬180 mFHC ¬110 The flag holder rotates 110°. 12. CHG ¬HGB mCHG ¬mHGB mCHG ¬70 (y y ) (x2 x1) 6 4 ¬ 93 1 ¬2 6 or 3

2 1 13. m ¬

14. The ball did not reach home plate. The distance between second base and home plate forms the hypotenuse of a right triangle, with second base to third base as one leg, and third base to home plate as the other leg. The Pythagorean Theorem is used to find the distance between second base and home plate. 902 902 ¬c2 8100 8100 ¬c2 16,200 ¬c2 16,20 0 ¬c 127.3 ¬c Since the ball traveled 120 feet and the distance from second base to home plate is about 127.3 feet, the ball did not make it to home plate.

Chapter 3

84

Chapter 4 Congruent Triangles Page 177

10. 12 is supplementary to 4 12 is supplementary to 16 12 is supplementary to 11

Getting Started

1. 2x 18 ¬5 2. 3m 16 ¬12 2x ¬13 3m ¬28 1 3 28 1 1 x ¬ or 6 m ¬ 2 2 3 or 9 3 3. 4y 12 ¬16 4. 10 ¬8 3z 4y ¬4 2 ¬3z y ¬1 5. 6 ¬2a 1 2 11 ¬2a 2 11 4 ¬a 2 3 4 ¬a

2 3 ¬z

12 is

6. 2 3 b 9 ¬15 2b ¬24 3

b ¬36

12 is

7. 8 2 8 12 8 15 8 6 8 9 8 3

vertical corresponding alternate exterior corresponding alternate exterior 8 15 alternate exterior , 15 3 alternate interior , transitivity 8 13 8 15 alternate exterior , 15 13 corresponding , transitivity 8. 13 2 13 15 corresponding , 15 2 corresponding , transitivity 13 12 alternate exterior 13 15 corresponding 13 6 alternate exterior 13 9 corresponding 13 3 vertical 13 8 13 15 corresponding , 15 8 alternate exterior , transitivity 9. 1 is supplementary to 6 linear pair 1 is supplementary to 9 linear pair 1 is supplementary to 3 consecutive interior 1 is supplementary to 13 1 is supplementary to 3, 3 13 vertical 1 is supplementary to 2 consecutive interior 1 is supplementary to 8 1 is supplementary to 2, 2 8 vertical 1 is supplementary to 12 1 10 corresponding , 10 is supplementary to 12 consecutive interior 1 is supplementary to 15 1 14 corresponding , 14 supplementary to 15 consecutive interior

12 is

12 is

12 is 11.

12.

13.

4-1

linear pair linear pair 12 3 corresponding , 3 is supplementary to 11 linear pair supplementary to 14 12 is supplementary to 16 linear pair, 16 14 corresponding supplementary to 5 12 is supplementary to 10 consecutive interior , 10 5 alternate exterior supplementary to 1 12 is supplementary to 10 consecutive interior , 10 1 corresponding supplementary to 7 12 8 corresponding , 8 is supplementary to 7 linear pair supplementary to 10 consecutive interior 2 2 d ¬(x x ) (y y 2 1 2 1) ¬(4 6)2 ) (3 82 ¬(10) 25) (2 ¬125 ¬11.2 2 d ¬(x x (y2 y1)2 2 1) ¬[6 15)] (28 (1) 122 2 ¬21 62 ¬477 ¬21.8 2 d ¬(x x (y2 y1)2 2 1) ¬(3 11)2 [4 (8)]2 ¬(14) 2 42 ¬212 ¬14.6

Classifying Triangles

Page 179 Geometry Activity: Equilateral Triangles 1. Yes, all edges of the paper are an equal length. 2. See students’ work. 3. See students’ work.

85

Chapter 4

Pages 180–181

12. 8 scalene triangles (green), 8 isosceles triangles in the middle (blue), 4 isosceles triangles around the middle (yellow), and 4 isosceles triangles at the corners of the square (purple).


1. Triangles are classified by sides and angles. For example, a triangle can have a right angle and have no two sides congruent. 2. Sample answer:

Pages 181–183 Practice and Apply 13. The triangle has a right angle, so it is a right triangle. 14. The triangle has three acute angles, so it is an acute triangle. 15. The triangle has three acute angles, so it is an acute triangle. 16. The triangle has one angle with measure greater than 90, so it is an obtuse triangle. 17. The triangle has one angle with measure greater than 90, so it is an obtuse triangle. 18. The triangle has a right angle, so it is a right triangle. 19. The triangle has three congruent sides and three congruent angles, so it is equilateral and equiangular. 20. See students’ work. 21. The triangles have two congruent sides, so they are isosceles. The triangles have three acute angles, so they are acute. 22. BGD is a right angle, so A D B C . Then AGB, AGC, DGB, and DGC are right angles, so AGB, AGC, DGB, and DGC are right triangles. 23. BAC and CDB are obtuse, so BAC and CDB are obtuse triangles. 24. AGB, AGC, DGB, and DGC are scalene because they each have no congruent sides. 25. ABD, ACD, BAC, and CDB are isosceles triangles because they each have two congruent sides. 26. H G J G so HG JG. x 7 ¬3x 5 7 5 ¬3x x 12 ¬2x 6 ¬x GH ¬x 7 ¬6 7 ¬13 GJ ¬3x 5 ¬3(6) 5 ¬13 HJ ¬x 1 ¬6 1 ¬5 27. MPN is equilateral so all three sides are congruent. MN ¬MP 3x 6 ¬x 4 3x x ¬4 6 2x ¬10 x ¬5 MN ¬3x 6 ¬3(5) 6 9 MP ¬x 4 ¬5 4 9 NP ¬2x 1 ¬2(5) 1 9

3. Always; equiangular triangles have three acute angles. 4. Never; right triangles have one right angle and acute triangles have all acute angles. 5. The triangle has one angle with measure greater than 90, so it is an obtuse triangle. 6. The triangle has three congruent angles, so it is an equiangular triangle. 7. MJK is obtuse because mMJK 90. KLM is obtuse because mKLM mMJK and mMJK 90. JKN is obtuse because mJNK 180 mJNM 180 52 or 128. LMN is obtuse because mLNM 180 mJNM 180 52 or 128. 8. GHD is a right triangle because G H D F so GHD is a right angle. GHJ is a right triangle because G H D F so GHJ is a right angle. IJF is a right triangle because IJ G H , H G D F so IJ D F and IJF is a right angle. EIG is a right triangle because G I E F so EIG is a right angle. 9. J M M N so JM MN. 2x 5 ¬3x 9 5 9 ¬3x 2x 4 ¬x JM ¬2x 5 ¬2(4) 5 ¬3 MN ¬3x 9 ¬3(4) 9 ¬3 JN ¬x 2 ¬4 2 ¬2 10. Since QRS is equilateral, each side has the same length. So QR RS. 4x ¬2x 1 2x ¬1 x ¬1 2 QR ¬4x

¬4 1 2 ¬2 RS ¬2x 1

¬2 1 2 1 ¬2 QS ¬6x 1

¬6 1 2 1 ¬2 2 ( 11. TW ¬(4 ) 25 6)2 ¬4 121 25 1 WZ ¬(3 4)2 5)] [0 (2 ¬49 5 2 74 TZ ¬(3 2)2 ) (0 62 ¬25 6 3 61 TWZ is scalene because no two sides are congruent.

Chapter 4

86

28. QRS is equilateral so all three sides are congruent. QR ¬2x 2 RS ¬x 6 QS ¬3x 10 QR ¬RS 2x 2 ¬x 6 2x x ¬6 2 x ¬8 QR ¬2x 2 ¬2(8) 2 ¬14 RS ¬x 6 ¬8 6 ¬14 QS ¬3x 10 ¬3(8) 10 ¬14 29. JL ¬2x 5 JK ¬x 3 KL ¬x 1 J K ¬L J KJ ¬LJ x 3 ¬2x 5 3 5 ¬2x x 8 ¬x JL ¬2x 5 ¬2(8) 5 ¬11 JK ¬x 3 ¬8 3 ¬11 KL ¬x 1 ¬8 1 ¬7 30. P is the midpoint of M N , so MP PN 1 2 (24) or 12. O P M N , so MPO and NPO are right triangles. Use the Pythagorean Theorem to find MO and NO. (MO)2 ¬(MP)2 (OP)2 (MO)2 ¬122 122 (MO)2 ¬288 MO ¬288 (NO)2 ¬(PN)2 (OP)2 (NO)2 ¬122 122 (NO)2 ¬288 NO ¬288 MPO and NPO are not equilateral because MO NO 288 . 31. Let x be the distance from Lexington to Nashville. Then the distance from Cairo to Nashville is x 40, the distance from Cairo to Lexington is x 81, and (x 40) (x 81) x 593 3x 41 ¬593 3x ¬552 x ¬184 x 40 ¬184 40 or 144 x 81 ¬184 81 or 265 The triangle formed is scalene; it is 184 miles from Lexington to Nashville, 265 miles from Cairo to Lexington, and 144 miles from Cairo to Nashville.

2 ( 32. AB ¬(3 ) 51 4)2 ¬4 25 29 2 [1)] BC ¬(7 ) 31 (2 ¬16 0 16 or 4 2 ( AC ¬(7 ) 51 4)2 ¬4 25 29 Since A B and A C have the same length, ABC is isosceles. 2 33. AB ¬[5 4)] ( (6 1)2 ¬81 5 2 106 BC ¬(3 5)2 (7 6)2 ¬64 69 1 233 AC ¬[3 (4)]27 ( 1)2 ¬1 64 65 ABC is scalene because no two sides are congruent. 34. AB ¬[7 (7)]21 () 92 ¬0 0 10 100 or 10 2 BC ¬[4 7)] ( [11)] (2 ¬121 0 121 or 11 2 AC ¬[4 7)] ( (1 9)2 ¬121 100 221 ABC is scalene because no two sides are congruent. 2 35. AB ¬[2 3)] ( [1 (1)]2 ¬25 4 29 2 ( BC ¬(2 ) 23 1)2 ¬0 16 16 or 4 2 AC ¬[2 3)] ( [31)] (2 ¬25 4 29 Since A B and A C have the same length, ABC is isosceles. 36. AB ¬ (53 0)2 (2 5)2 ¬75 9 84 BC ¬ (0 5 3 )2 (1 2)2 ¬75 9 84 2 () AC ¬(0 ) 01 52 ¬0 36 36 or 6 Since A B and B C have the same length, ABC is isosceles. 37. AB ¬ [5 (9)]2 (6 3 0)2 ¬16 08 1 124 BC ¬ [1 (5)]2 (0 63 )2 ¬16 08 1 124 AC ¬[1 (9)]2 (0 0)2 ¬64 0 64 or 8 Since A B and B C have the same length, ABC is isosceles.

87

Chapter 4

38. Given: EUI is equiangular. L Q U I Prove: EQL is equiangular. E

Q

42. Use the Distance Formula and Slope Formula. 2 (2 KL ¬(4 ) 2 6)2 ¬4 16 ¬20 L K L M , so LM 20 . 2 6 L ¬ slope of K 42

4 ¬ 2 or 2 KLM is a right angle, so K L L M and L M has slope 1 2. Let (x2, y2) be the coordinates of M.

L

U Proof: Statements

I

y 2 x2 4 y2 2 1 ¬ 2 x2 4

2 slope of L M ¬

Reasons

1. EUI is equiangular. L Q U I

1. Given

2. E EUI EIU

2. Definition of equiangular triangle

3. EUI EQL EIU ELQ

3. Corresponding are .

4. E E

4. Reflexive Property

x2 4 ¬2(y2 2) 2 2) 2 LM ¬(x 4) 2 (y 2 2 20 ¬[2(y 2)] (y 2)2 2 2 2 20 ¬4(y 2) (y2 2)2 2 2 20 ¬5(y 2) 2 20 ¬5(y2 2)2 4 ¬(y2 2)2 2 ¬y2 2 or 2 y2 2 or 0 y2 4 ¬y2 x2 ¬2(y2 2) 4 x2 ¬2(4 2) 4 or x2 2(0 2) 4 x2 ¬8 or x2 0 M has coordinates (8, 4) or (0, 0). 43. Sample answer: Triangles are used in construction as structural support. Answers should include the following. • Triangles can be classified by sides and angles. If the measure of each angle is less than 90, the triangle is acute. If the measure of one angle is greater than 90, the triangle is obtuse. If one angle equals 90°, the triangle is right. If each angle has the same measure, the triangle is equiangular. If no two sides are congruent, the triangle is scalene. If at least two sides are congruent, it is isosceles. If all of the sides are congruent, the triangle is equilateral. • Isosceles triangles seem to be used more often in architecture and construction. 2 44. C; AB ¬[1 1)] ( (3 1)2 ¬4 4 8 2 () BC ¬(3 ) 11 32 ¬4 16 20 2 AC ¬[3 1)] ( (1 1)2 ¬16 4 20 Since A C and B C have the same length, ABC is isosceles.

5. E EQL ELQ 5. Transitive Property 6. EQL is equiangular.

6. Definition of equiangular triangles

39. Given: mNPM 33 Prove: RPM is obtuse. M N 33

P R Proof: NPM and RPM form a linear pair. NPM and RPM are supplementary because if two angles form a linear pair, then they are supplementary. So, mNPM mRPM 180. It is given that mNPM 33. By substitution, 33 mRPM 180. Subtract to find that mRPM 147. RPM is obtuse by definition. RPM is obtuse by definition. 40. TS [7 (4)]2 (8 14)2 9 36 or 45 2 ( SR [10 )] (72 8)2 9 36 or 45 S is the midpoint of R T . 2 UT [0 4)] ( (8 14)2 16 6 3 or 52 2 (2 VU (4 ) 0 8)2 16 6 3 or 52 U is the midpoint of T V .

y

(0 b) 0 a2 a4 b ¬ a (b ) 2 CD ¬ a a b) (0 2 a a4 b ¬ (b) 2 2

41. AD ¬

2

2

2

2

2

B

2

A x

2

C

2

2

2

2

All three angles of ABC are acute, so ABC is acute.

AD CD, so A D C D . ADC is isosceles by definition. Chapter 4

88

x y 15 35 45. B; ¬25

The perpendicular segment from the point (6, 2) to the line y 7 intersects the line y 7 at (6, 7). Use the Distance Formula to find the distance between (6, 2) and y 7. 2 d ¬(x x (y2 y1)2 2 1) 2 ¬(6 ) 62 ( 7)2 ¬0 81 ¬81 or 9 The distance between the line y 7 and the point (6, 2) is 9 units.

4

x y 50 ¬100 x y ¬50

x 15 35 ¬27 3

x 50 ¬81 x ¬31

Substituting 31 for x, 31 y ¬50 y ¬19 49.

C

Page 183 Maintain Your Skills 46.

D E (4x

x

Explore: From the figure, you know that mABC 110 and mDEF 4x 10. Plan: For line p to be parallel to line q, corresponding angles must be congruent, so ABC AED. Since AED is supplementary to DEF because they are a linear pair, it must be true that p q if ABC is supplementary to DEF, or mABC mDEF 180. Substitute the given angle measures into this equation and solve for x. Solve: mABC mDEF ¬180 110 4x 10 ¬180 4x ¬60 x ¬15 Examine: Verify the measure of DEF by using the value of x. That is, 4x 10 4(15) 10 or 70, and 110 70 180. Since mABC mDEF 180, ABC is supplementary to DEF and p q.

x (2, –2)

The perpendicular segment from the point (2, 2) to the line y x 2 appears to intersect the line y x 2 at (1, 1). Use the Distance Formula to find the distance between (2, 2) and y x 2. 2 d ¬(x x (y2 y1)2 2 1) 2 ¬(1 2) 2)] [1 (2 ¬9 9 ¬18 The distance between the line y x 2 and the point (2, 2) is 18 units. y (3, 3) x

y

50.

2

p

x

O

F

E B

(2x

5)˚

D Explore: From the figure, you know that mABC 3x 50 and mDEF 2x 5. You also know that ABC and DEF are alternate exterior angles. Plan: For line p to be parallel to line q, the alternate exterior angles must be congruent. So mABC mDEF. Substitute the given angle measures into this equation and solve for x. Solve: mABC ¬mDEF 3x 50 ¬2x 5 x ¬45 Examine: Verify the angle measures by using the value of x to find mABC and mDEF. mABC ¬3x 50 ¬3(45) 50 ¬85 mDEF ¬2x 5 ¬2(45) 5 ¬85 Since mABC mDEF, ABC DEF and p q.

y 7

x

O

50)˚

C

xy2 y x 2 The perpendicular segment from the point (3, 3) to the line x y 2 appears to intersect the line x y 2 at (1, 1). Use the Distance Formula to find the distance between (3, 3) and x y 2. 2 d ¬(x x (y2 y1)2 2 1) 2 (3 ¬(3 ) 1 1)2 ¬4 4 ¬8 The distance between the line x y 2 and the point (3, 3) is 8 units.

y

q

A (3x

48.

q

F

10)˚

2

O

47.

p

B

y y

A

110˚

(6, –2)

89

Chapter 4

51.

A 57˚

B E F

52.

53. 54. 55. 56. 57.

C D

(3x

Angles of Triangles

4-2

p q

Pages 188–189 Check for Understanding 1. Sample answer: 2 and 3 are the remote interior angles of exterior 1.

9)˚

Explore: From the figure, you know that mABC 57 and mDEF 3x 9. Plan: For line p to be parallel to line q, corresponding angles must be congruent, so ABC AED. Since AED is supplementary to DEF, because they are a linear pair, it must be true that p q if ABC is supplementary to DEF, or mABC mDEF 180. Substitute the given angle measures into this equation and solve for x. Solve: mABC mDEF ¬180 57 3x 9 ¬180 3x ¬132 x ¬44 Examine: Verify the measure of DEF by using the value of x. That is, 3x 9 3(44) 9 or 123, and 57 123 180. Since mABC mDEF 180, mABC is supplementary to DEF, and p q. 1. Given 2. Subtraction Property 3. Addition Property 4. Division Property any three: 2 and 11, 3 and 6, 4 and 7, 3 and 12, 7 and 10, 8 and 11 1 and 4, 1 and 10, 5 and 2, 5 and 8, 9 and 6, 9 and 12 6, 9, and 12 by alternate interior and transitivity 1, 4, and 10 by alternate interior and transitivity 2, 5, and 8 by alternate interior and transitivity

2 1

2. Najee; the sum of the measures of the remote interior angles is equal to the measure of the corresponding exterior angle. 3. Let P be the unknown angle at Pittsburgh. mP 85 52 ¬180 mP 137 ¬180 mP ¬43 4. Let A be the unknown angle in the figure. mA 62 19 ¬180 mA 81 ¬180 mA ¬99 5. m1 23 32 55 6. m2 22 ¬m1 m2 22 ¬55 m2 ¬33 7. m3 22 (180 m1) 22 180 55 147 8. m1 25 ¬90 m1 ¬65 9. m2 65 90 m2 ¬25 10. m1 m2 ¬90 m1 70 ¬90 m1 ¬20

Pages 189–191

5. 6. 7. 8. 9. 10. 11. 12.

congruent congruent congruent 180, because DFA DFE AFE, and AFE and EFC form a linear pair. mA mB mC 180 by substitution The sum of the measures of the angles of any triangle is 180. mA mB is the measure of the exterior angle at C. See students’ work. yes See students’ work. See students’ work. The measure of an exterior angle is equal to the sum of the measures of the two remote interior angles.

Chapter 4

Practice and Apply

11. Let X be the third angle in the triangle. mX 40 47 ¬180 mX 87 ¬180 mX ¬93 12. Let X be one of the two congruent angles of the triangle. mX mX 39 ¬180 2mX 39 ¬180 2mX ¬141 mX ¬70.5 The missing angles have measure 70.5 and 70.5. 13. Let X be one of the two congruent angles of the triangle. mX mX 50 ¬180 2mX 50 ¬180 2mX ¬130 mX ¬65 The missing angles have measure 65 and 65.

Page 184 Geometry Activity: Angles of Triangles 1. 2. 3. 4.

3

90

14. Let X be the unknown acute angle of the triangle. mX 27 ¬90 mX ¬63 15. m1 47 57 ¬180 m1 104 ¬180 m1 ¬76 16. m2 m1 m2 76 17. m3 m2 55 ¬180 m3 76 55 ¬180 m3 131 ¬180 m3 ¬49 18. m1 69 47 ¬180 m1 116 ¬180 m1 ¬64 19. m1 m2 63 ¬180 64 m2 63 ¬180 m2 127 ¬180 m2 ¬53 20. m3 m2 63 53 63 116 21. m4 m5 m3 ¬180 2m4 116 ¬180 2m4 ¬64 m4 ¬32 22. m5 m4 23. m6 136 ¬180 m5 32 m6 ¬44 24. m7 47 ¬136 m7 ¬89 25. m1 33 24 ¬180 m1 57 ¬180 m1 ¬123 26. m2 95 ¬m1 m2 95 ¬123 m2 ¬28 27. m3 109 ¬m1 m3 109 ¬123 m3 ¬14 28. m1 126 ¬180 29. m2 73 ¬126 m1 ¬54 m2 ¬53 30. m3 43 ¬180 m3 ¬137 31. m4 34 43 ¬180 m4 77 ¬180 m4 ¬103 32. m1 mDGF ¬90 m1 53 ¬90 m1 ¬37 33. m2 mAGC ¬90 m2 40 ¬90 m2 ¬50 34. m3 mAGC ¬90 m3 40 ¬90 m3 ¬50

35. m4 m2 ¬90 m4 50 ¬90 m4 ¬40 36. m1 26 101 ¬180 m1 127 ¬180 m1 ¬53 37. m2 26 103 129 38. m3 101 (180 128) 153 39. Given: FGI IGH G I F H Prove: F H G

F I H Proof: GI ⊥ FH Given

GIF and GIH are right angles.

FGI

⊥ lines form rt. .

GIF All rt.

IGH

Given

GIH

F

H

Third Angle Theorem

are .

40. Given: ABCD is a quadrilateral. Prove: mDAB mB mBCD mD 360 A B 1 2

4

D Proof: Statements

3

C Reasons

1. ABCD is a quadrilateral.

1. Given

2. m2 m3 mB 180 m1 m4 mD 180 3. m2 m3 mB m1 m4 mD 360

2. Angle Sum Theorem 3. Addition Property

4. mDAB m1 m2 mBCD m3 m4

4. Angle addition

5. mDAB mB mBCD 5. Substitution mD 360

91

Chapter 4

41. Given: ABC Prove: mCBD mA mC C

Given: PQR P is obtuse. Prove: There can be at most one obtuse angle in a triangle. Q

D

A

B

R P Proof: In PQR, P is obtuse. So mP 90. mP mQ mR 180. It must be that mQ mR 90. So, Q and R must be acute. 44. Given: A D B E Prove: C F

Proof: Statements

Reasons

1. ABC

1. Given

2. CBD and ABC form a linear pair.


3. CBD and ABC are supplementary.

3. If 2 form a linear pair, they are suppl.

F

4. mCBD mABC 180 4. Def. of suppl. 5. mA mABC mC 180

5. Angle Sum Theorem

6. mA mABC mC mCBD mABC

6. Subsitution Property

7. mA mC mCBD

7. Subtraction Property

C A

T

Proof: Given

m R

90

m S

m T

1. Given

2. mA mD mB mE

2. Def. of

3. mA mB mC 180 mD mE mF 180


4. mA mB mC mD mE mF


5. mD mE mC mD mE mF

5. Substitution Property

6. mC mF

6. Subtraction Property

7. C F

7. Def. of

45. m1 m2 m3 ¬180 4x 5x 6x ¬180 15x ¬180 x ¬12 m1 4(12) or 48 m2 5(12) or 60 m3 6(12) or 72 46. Sample answer: The shape of a kite is symmetric. If triangles are used on one side of the kite, congruent triangles are used on the opposite side. The wings of this kite are made from congruent right triangles. Answers should include the following. • By the Third Angle Theorem, if two angles of two congruent triangles are congruent, then the third angles of each triangle are congruent. • If one angle measures 90, the other two angles are both acute. 47. A; mZ mX ¬90 a 2 2a ¬90 a 4a ¬180 5a ¬180 a ¬36 mZ ¬a 2

180

Angle Sum Theorem

Def. of rt. 90

m S

m T

180

Substitution

m S

m T

90

Subtraction Prop.

S and T are complementary Def. of complementary

43. Given: MNO N M is a right angle. M O Prove: There can be at most one right angle in a triangle. Proof: In MNO, M is a right angle. mM mN mO 180. mM 90, so mN mO 90. If N were a right angle, then mO 0. But that is impossible, so there cannot be two right angles in a triangle. Chapter 4

Reasons

1. A D B E

R is a rt. .

m R

E

Proof: Statements

42. Given: RST R is a right angle Prove: S and T are complementary S R

D B

3 6 ¬ 2 or 18

92

2 d ¬(x x (y2 y1)2 2 1) 2 ¬(4 0 ) ) (1 32 ¬16 4 ¬20 The distance between the lines is 25 units. 54. 4x y ¬20 y ¬4x 20 y ¬4x 20 4x y ¬3 y ¬4x 3 y ¬4x 3 First, write an equation of a line p perpendicular to 4x y 20 and 4x y 3. The slope of p is the opposite reciprocal of 4, or 1 4 . Use the y-intercept of 4x y 20, (0, 20), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1)

48. B; let x be the measure of the first angle. Then the other angles have measure 3x and x 25. x 3x x 25 ¬180 5x 25 ¬180 5x ¬155 x ¬31 3x ¬3(31) or 93 x 25 ¬31 25 or 56

Page 191


49. AED is scalene because no two sides are congruent. 50. AED is obtuse because mAED 90. mAED mBEC, so BEC is obtuse. 51. BEC is isosceles because E B E C . 52. First, write an equation of a line p perpendicular to y x 6 and y x 10. The slope of p is the opposite reciprocal of 1, or 1. Use the y-intercept of y x 6, (0, 6), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1) y 6 ¬1(x 0) y 6 ¬x y ¬x 6 Next, use a system of equations to determine the point of intersection of line y x 10 and p. x 10 ¬x 6 2x ¬16 x ¬8 y 8 10 y 2 The point of intersection is (8, 2). Then, use the Distance Formula to determine the distance between (0, 6) and (8, 2). 2 d ¬(x x (y2 y1)2 2 1) 2 ¬(8 ) 02 () 62 ¬64 4 6 ¬128 The distance between the lines is 82 units. 53. First, write an equation of a line p perpendicular to y 2x 3 and y 2x 7. The slope of p is the opposite reciprocal of 2, or 1 2 . Use the y-intercept of y 2x 3, (0, 3), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1)

y (20) ¬1 4 (x 0) y 20 ¬1 4x

y ¬1 4 x 20 Next, use a system of equations to determine the point of intersection of line 4x y 3 and p. 4x 3 ¬1 4 x 20 1 7 4 x ¬17

x ¬4

y 1 4 (4) 20 y 19 The point of intersection is (4,19). Then, use the Distance Formula to determine the distance between (0, 20) and (4,19). 2 d ¬(x x (y2 y1)2 2 1) 2 ¬(4 0) [190)] (22 ¬16 1 ¬17 The distance between the lines is 17 units. 55. 2x 3y ¬9 3y ¬2x 9 y ¬2 3x 3 2x 3y ¬6 3y ¬2x 6 y ¬2 3x 2 First, write an equation of a line p perpendicular to 2x 3y 9 and 2x 3y 6. The slope of p 3 is the opposite reciprocal of 2 3 , or 2 . Use the y-intercept of 2x 3y 9, (0, 3), as one of the endpoints of the perpendicular segment. y y1 ¬m(x x1)

y 3 ¬1 2 (x 0) y 3 ¬1 2x y ¬1 2x 3 Next, use a system of equations to determine the point of intersection of line y 2x 7 and p. 2x 7 ¬1 2x 3

y 3 ¬3 2 (x 0)

y 3 ¬3 2x

y ¬3 2x 3 Next, use a system of equations to determine the point of intersection of line 2x 3y 6 and p.

5 2 x ¬10 x ¬4 y 2(4) 7 y1 The point of intersection is (4, 1). Then, use the Distance Formula to determine the distance between (0, 3), and (4, 1).

2 x 2 ¬3 x 3 3 2 1 3 x ¬1 6 6 x ¬ 13

93

Chapter 4

6. The red triangles are congruent: BME, ANG, DKH, CLF. The blue triangles are congruent: EMJ, GNJ, HKJ, FLJ. The purple triangles are congruent to each other and to the triangles made up of a blue triangle and a red triangle: BLJ, AMJ, JND, JKC, BMJ, ANJ, JKD, JLC. Another set of congruent triangles consists of triangles made up of a red, a blue, and a purple triangle: BAJ, ADJ, DCJ, CBJ. Another set of congruent triangles consists of the triangles which are each half of the square: BCD, ADC, CBA, DAB. 7. y

6 y 3 2 13 3 9 30 y 13 3 or 13 6 30 The point of intersection is 13 , 13 . Then, use the Distance Formula to determine the 6 30 . distance between (0, 3) and 1 3 , 13

d

2 ¬(x x (y2 y1)2 2 1)

0 3 163 3103

¬

2

2

1 11 7 17 ¬ 169 or 13 36 8 1 ¬ 169 169

56. 2y 8 142 ¬180 linear pair 2y 150 ¬180 2y ¬30 y ¬15 4x 6 ¬142 corresponding angles 4x ¬136 x ¬34 z ¬4x 6 alternate exterior angles z ¬4(34) 6 z ¬142 57. x 68 ¬180 supplementary consecutive interior angles x ¬112 4y 68 ¬180 linear pair 4y ¬112 y ¬28 5z 2 ¬x alternate interior angles 5z 2 ¬112 5z ¬110 z ¬22 58. 3x ¬48 alternate interior angles x ¬16 y 42 48 ¬180 Angle Sum Theorem y 90 ¬180 y ¬90 z 42 alternate interior angles 59. reflexive 60. symmetric 61. symmetric 62. transitive 63. transitive 64. transitive

4-3

x

R

T

T’

R’

Use the Distance Formula to find the length of each side in the triangles. QR ¬[4 (4)]22 () 32 ¬0 25 or 5 2 () QR ¬(4 ) 42 32 ¬0 25 or 5 RT ¬[1 (4)]22 [2)] (2 ¬9 0 or 3 2 [2)] RT ¬(1 ) 42 (2 ¬9 0 or 3 QT ¬[1 (4)]22 ( 3)2 ¬9 25 or 34 2 ( QT ¬(1 ) 42 3)2 ¬9 25 or 34 The lengths of the corresponding sides of two triangles are equal. Therefore, by the definition of congruence, Q R Q R , R T R T , and T Q Q T . Use a protractor to measure the angles of the triangles. You will find that the measures are the same. In conclusion, because R Q QR, R T R T , Q T Q T , Q Q, R R, and T T, QRT QRT. QRT is a flip of QRT. 8. G K, H L, J P, G H K L , J H L P , G J K P

Congruent Triangles

Pages 195–198 Practice and Apply 9. CFH JKL 10. RSV TSV 11. WPZ QVS 12. EFH GHF 13. T X, U Y, V Z, T U X Y , V U Y Z , T V X Z 14. C R, D S, G W, C D R S , G D S W , C G R W 15. B D, C G, F H, B C D G , F C G H , B F D H 16. A H, D K, G L, A D H K , G D K L , A G H L 17. 1 10, 2 9, 3 8, 4 7, 5 6 18. s 1–4, s 5–12, s 13–20

Page 195 Check for Understanding 1. The sides and the angles of the triangle are not affected by a congruence transformation, so congruence is preserved. 2. Sample answer:

3. AFC DFB 4. HJT TKH 5. W S, X T, Z J, W X S T , Z X T J , W Z S J Chapter 4

Q’

Q

1 17 The distance between the lines is 1 3 units.

94

19. s 1, 5, 6, and 11, s 3, 8, 10, and 12, s 2, 4, 7, and 9 20. UFS, TDV, ACB 21. We need to know that all the corresponding angles are congruent and that the other corresponding sides are congruent. 22. Use the figure and the Distance Formula to find the length of each side in the triangles. PQ ¬2 PQ ¬2 QV ¬4 QV ¬4 PV ¬[2 (4)]2 (4 8)2 ¬4 16 or 20 2 (4 PV ¬(2 ) 4 8)2 ¬4 16 or 20 The lengths of the corresponding sides of the two triangles are equal. Therefore, by the definition of congruence, P Q P Q , Q V Q V , and V P P V . Use a protractor to confirm that the corresponding angles are congruent. Therefore, PQV PQV. PQV is a flip of PQV. 23. Use the figure and the Distance Formula to find the length of each side in the triangles. MN ¬8 MN ¬8 NP ¬2 NP ¬2 2 MP ¬[2 6)] ( (2 4)2 ¬64 4 or 68 2 MP ¬[2 6)] ( [24)] (2 ¬64 4 or 68 The lengths of the corresponding sides of the two triangles are equal. Therefore, by the definition of congruence, M N M N , N P N P , and P M M P . Use a protractor to confirm that the corresponding angles are congruent. Therefore, MNP MNP. MNP is a flip of MNP. 24. Use the figure and the Distance Formula to find the length of each side in the triangles. 2 (3 GF ¬(5 ) 2 2)2 ¬9 1 or 10 GF ¬(12 9)2 2) (3 2 ¬9 1 or 10 2 (5 GH ¬(3 ) 2 2)2 ¬1 9 or 10 GH ¬(10 9)2 2) (5 2 ¬1 9 or 10 2 (3 HF ¬(5 ) 3 5)2 ¬4 4 or 8 HF ¬(12 10)2 5) (3 2 ¬4 4 or 8 The lengths of the corresponding sides of the two triangles are equal. Therefore, by the definition of congruence, G F G F , G H G H , and F H H F . Use a protractor to confirm that the corresponding angles are congruent.

Therefore, GHF GHF. GHF is a slide of GHF. 25. Use the figure and the Distance Formula to find the length of each side in the triangles. JK ¬[2 (4)]23 () 32 ¬4 36 or 40 2 [3)] JK ¬(8 ) 21 (2 ¬36 4 or 40 2 KL¬[0 2)] ( [2 (3)]2 ¬4 25 or 29 2 [11)] KL ¬(3 ) 8 (2 ¬25 4 or 29 2 JL ¬[0 4)] ( (2 3)2 ¬16 1 or 17 2 [13)] JL ¬(3 ) 2 (2 ¬1 16 or 17 The lengths of the corresponding sides of the two triangles are equal. Therefore, by the definition of congruence, J K J K , K L K L , and J L J L . Use a protractor to confirm that the corresponding angles are congruent. Therefore, JKL JKL. JKL is a turn of JKL. 26. False; A X, B Y, and C Z but the corresponding sides are not congruent. Y B X

Z

A 27. True;

C D A E

F

B C 28. Both statements are correct because the spokes are the same length, E A IA , and A E A I. 29. 12 H J 6

10

12

R

S

G

6

10

Q 30. HJ corresponds to R S , so H J R S . 2x – 4 ¬12 2x ¬16 x ¬8 31. K 64

J

36

80

E L 36

64 80

D F 32. D J, so mD mJ 36. mD mE mF ¬180 36 64 3x 52 ¬180 3x 152 ¬180 3x ¬28 28 x ¬ 3

95

Chapter 4

33. Given: RST XYZ Prove: XYZ RST R S X

Page 198 Maintain Your Skills 40. x 40 ¬115 41. x 42 ¬100 x ¬75 x ¬58 42. x x 30 ¬180 2x ¬150 x ¬75 43. B C C D , so BC CD. 2x 4 ¬10 2x ¬6 x ¬3 BC 2x 4 2(3) 4 or 10 CD 10 BD x 2 3 2 or 5 44. HKT is equilateral, so H K H T hence HK HT. x 7 ¬4x 8 15 ¬3x 5 ¬x HK KT HT 4x 8 4(5) 8 or 12

Y

T

Z

Proof: RST

XYZ

Given

R X, S Y, T Z, RS XY, ST YZ, RT XZ CPCTC

X XY

R, Y S, Z T, RS, YZ ST, XZ RT

Congruence of and segments is symmetric.

XYZ

RST

Def. of

34. a. Given b. Given c. Congruence of segments is reflexive. d. Given e. Def. of lines f. Given g. Def. of lines h. All right are . i. Given j. Alt. int. are . k. Given l. Alt. int. are . m. Def. of s 35. Given: DEF E Prove: DEF DEF D

(y y )

2 1 45. m ¬ (x x ) 2

46. y ¬mx b y ¬3 4x 8 47.

48. F

Proof: 49.

DEF Given

DE DE, EF DF DF

EF,

Congruence of segments is reflexive.

D F

D, E F

E,

50.

Congruence of is reflexive.

51. DEF

DEF

Def. of

36. SMP TNP, MPS NPT 37. Sample answer: Triangles are used in bridge design for structure and support. Answers should include the following. • The shape of the triangle does not matter. • Some of the triangles used in the bridge supports seem to be congruent. 38. B; by the order of the vertices in the triangle names, A C X Z 2 39. D; DF [3 5)] ( (7 4)2 64 21 1 or 185

Chapter 4

1

3 3 3 ¬ 4 0 or 2 y ¬mx b y ¬ 3 2x 3

m ¬4 y y1 ¬m(x x1) y 1 ¬4[x (3)] y 1 ¬4x 12 y ¬4x 11 y y1 ¬m(x x1) y 2 ¬4[x (3)] y 2 ¬4x 12 y ¬4x 10 2 d ¬(x x (y2 y1)2 2 1) 2 ¬[1 1)] ( (6 7)2 ¬4 1 or 5 2 d ¬(x x (y2 y1)2 2 1) 2 ¬(4 ) 82 () 22 ¬16 6 1 or 32 2 d ¬(x x (y2 y1)2 2 1) 2 2 ¬(5 ) 3 (2 5) ¬4 9 or 13

Page 198 Practice Quiz 1 1. The segments F J , G J , H J , and D J are all congruent. So DFJ, GJF, HJG, and DJH are isosceles triangles because they each have a pair of congruent sides. 2. ABC is equilateral, so all sides are congruent. 2x ¬4x 7 2x ¬7 x ¬3.5

96

3. AB 2x 2(3.5) or 7 BC 4x 7 4(3.5) 7 or 7 AC x 3.5 3.5 3.5 or 7 4. m1 50 70 ¬180 m1 120 ¬180 m1 ¬60 m2 m1 50 60 50 or 110 m3 m2 21 ¬180 m3 110 21 ¬180 m3 ¬49 5. M J, N K, P L; N M J K , N P K L , M P J L

2 (1 NP ¬(3 ) 4 6)2 ¬1 25 or 26 EF ¬[4 (2)]2 [62)] (2 ¬4 64 or 68 2 (6 MN ¬(4 ) 2 2)2 ¬4 16 or 20 The corresponding sides are not congruent, so the triangles are not congruent. 5. Given: D E and B C B bisect each other. Prove: DGB EGC D E G

C Proof: DE and BC bisect each other. Given

Page 199 Reading Mathematics 1. Sample answer: If side lengths are given, determine the number of congruent sides and name the triangle. Some isosceles triangles are equilateral triangles. 2. ABC is obtuse because mC 90. 3. equiangular or equilateral

4-4

DG

GE, BG

GC

Def. of bisector of segments

DGB

EGC

SAS

DGB Vertical

6. Given: K M J L , K M J L Prove: JKM MLJ

Proving Congruence—SSS, SAS

EGC are .

K J

M L

Pages 203–204 Check for Understanding

Proof:

1. Sample answer: In QRS, R is the included angle of the sides Q R and R S . R S

Statements

Reasons

1. K M J L , K M J L 1. Given

Q 2. Jonathan; the measure of DEF is needed to use SAS. 3. EG ¬[2 (4)]23 [3)] (2 ¬4 0 or 2 2 [3)] MP ¬(2 ) 43 (2 ¬4 0 or 2 FG ¬[2 (2)]23 () 12 ¬0 16 or 4 2 () NP ¬(2 ) 23 12 ¬0 16 or 4 EF ¬[2 (4)]2 [1)] (32 ¬4 16 or 20 2 [13)] MN ¬(2 ) 4 (2 ¬4 16 or 20 EG MP, FG NP, and EF MN. The corresponding sides have the same measure and are congruent. EFG MNP by SSS. 4. EG ¬[3 (2)]2 [12)] (2 ¬1 9 or 10 2 (1 MP ¬(3 ) 2 2)2 ¬1 1 or 2 FG ¬[3 (4)]2 (1 6)2 ¬1 25 or 26

2. KMJ LJM

2. Alt. int. are .

M J M 3. J


4. JKM MLJ

4. SAS

7. The triangles have two pairs of sides and the included angles congruent, so the triangles are congruent by the SAS postulate. 8. Each pair of corresponding sides are congruent, so the triangles are congruent by the SSS postulate. 9. Given: T is the midpoint of S Q . R R S Q R Prove: SRT QRT S Q T Proof: Statements

Reasons

1. T is the midpoint of S Q . 1. Given

97

2. S T T Q

2. Midpoint Theorem

3. S R Q R

3. Given

4. R T R T 5. SRT QRT

4. Reflexive Property 5. SSS

Chapter 4

14. Given: A E F C , A B B C , B E B F Prove: AFB CEB

Pages 204–206 Practice and Apply 10. JK ¬[7 (3)]2 (4 2)2 ¬16 4 or 20 2 (7 FG ¬(4 ) 2 3)2 ¬4 16 or 20 KL ¬[1 (7)]2 (9 4)2 ¬36 5 2 or 61 2 (1 GH ¬(9 ) 4 7)2 ¬25 6 3 or 61 JL ¬[1 (3)]2 (9 2)2 ¬4 49 or 53 2 (1 FH ¬(9 ) 2 3)2 ¬49 4 or 53 Each pair of corresponding sides has the same measure so they are congruent. JKL FGH by SSS. 11. JK ¬[2 (1)]22 () 12 ¬1 9 or 10 2 [1)] FG ¬(3 ) 22 (2 ¬1 1 or 2 KL ¬[5 (2)]21 [2)] (2 ¬9 1 or 10 2 [52)] GH ¬(2 ) 3 (2 ¬1 49 or 50 JL ¬[5 (1)]21 () 12 ¬16 4 or 20 2 [51)] FH ¬(2 ) 2 (2 ¬0 36 or 6 The corresponding sides are not congruent, so JKL is not congruent to FGH. 2 12. JK ¬[0 1)] ( [6 (1)]2 ¬1 49 or 50 2 (3 FG ¬(5 ) 3 1)2 ¬4 4 or 8 2 (3 KL ¬(2 ) 0 6)2 ¬4 9 or 13 2 (1 GH ¬(8 ) 5 3)2 ¬9 4 or 13 2 JL ¬[2 1)] ( [3 (1)]2 ¬9 16 or 5 2 (1 FH ¬(8 ) 3 1)2 ¬25 0 or 5 The corresponding sides are not congruent, so JKL is not congruent to FGH. 2 (6 13. JK ¬(4 ) 3 9)2 ¬1 9 or 10 2 (4 FG ¬(2 ) 1 7)2 ¬1 9 or 10 2 (5 KL ¬(1 ) 4 6)2 ¬9 1 or 10 GH ¬(1 2)2 4) (3 2 ¬9 1 or 10 2 (5 JL ¬(1 ) 3 9)2 ¬4 16 or 20 FH ¬(1 1)2 7) (3 2 ¬4 16 or 20 The corresponding sides have the same measure so they are congruent. JKL FGH by SSS.

Chapter 4

B

C F

A E Proof: AE

FC

Given

AE

FC

Def. of

AE

EF

seg.

EF

FC

EF

Addition Prop.

AE

EF

Reflexive Prop.

EC

AE EF AF EF FC EC

Substitution

Seg. Addition Post.

AF

EC

Def. of

AFB

seg.

AB BC BE BF

CEB

SSS

Given

RQ T Q Y Q W Q 15. Given: RQY WQT Prove: QWT QYR

R Y

Q

W

T

Proof: RQ

TQ

YQ

WQ

Given

RQY

WQT

Given

QWT

QYR

SAS

16. Given: CDE is an isosceles triangle. G is the midpoint of C E . Prove: CDG EDG D

C Proof:

98

G

E

Statements

Reasons

1. CDE is an isosceles triangle, G is the midpoint of C E .

1. Given

2. C D D E

2. Def. of isos.

3. C G G E

3. Midpoint Th.

4. D G D G 5. CDG EDG


17. Given: MRN QRP, MNP QPN Prove: MNP QPN M

Q

R N

Proof:

3. R P

3. Third Angle Theorem

4. RST PNM

4. SAS

21. Given: EF H F G is the midpoint of E H . Prove: EFG HFG H

P

Statements

Reasons

1. MRN QRP, MNP QPN

1. Given

N Q P 2. M

2. CPCTC

3. N P N P


Proof:

4. MNP QPN

4. SAS

Statements

Reasons

1. EF H F ; G is the midpoint of E H .

1. Given

2. E G G H

2. Midpoint Theorem

G F G 3. F


4. EFG HFG

4. SSS

F

AC G C 18. Given: C E bisects A G . Prove: GEC AEC

E

A E

C

G Proof: Statements

Reasons

1. AC G C , E C bisects A G .

1. Given

E E G 2. A

2. Def. of segment bisector

3. E C E C


4. GEC AEC

4. SSS

19. Given: GHJ LKJ Prove: GHL LKG

H

22. Each pair of corresponding sides is congruent. The triangles are congruent by the SSS Postulate. 23. The triangles have two pairs of corresponding sides congruent and one pair of angles congruent but what is needed is the pair of included angles to be congruent. It is not possible to prove the triangles are congruent. 24. The triangles have one pair of angles congruent and one pair of sides (the shared side) congruent. It is not possible to prove the triangles are congruent. 25. The triangles have three pairs of corresponding sides congruent and one pair of corresponding angles congruent. The triangles are congruent by the SSS or SAS Postulates. 26. Given: T S S F F H H T S TSF, SFH, FHT, and HTS are right P T F angles.

K J

G

L

Proof: Statements

Reasons

1. GHJ LKJ

1. Given

HJ K J , G J L J , 2. H G L K

2. CPCTC

Prove: H S T F

3. HJ KJ, GJ LJ

3. Def. of segments

4. HJ LJ KJ JG

4. Addition Property

5. KJ GJ KG; HJ LJ HL

5. Segment Addition

6. KG HL

6. Substitution

7. K G H L

7. Def. of segments 8. Reflexive Property

8. G L G L 9. GHL LKG

G

H Proof:

9. SSS

RS P N 20. Given: T R M P S S N M T M T Prove: RST PNM R Proof: Statements Reasons 1. R S P N , R T M P

1. Given

2. S N, and T M

2. Given

N

Statements

Reasons

1. TS S F F H H T 2. TSF, SFH, FHT, and HTS are right angles. 3. STH THF

1. Given 2. Given

4. STH THF

4. SAS

5. H S T F

5. CPCTC

3. All right are .

P

99

Chapter 4

27. Given: TS S F F H H T TSF, SFH, FHT, and HTS are right angles. T Prove: SHT SHF

30. C; using vertical angles and exterior angles, a b 90. Given this fact, it is impossible for the other statements to be true. 31. B; 3x 6x 7x ¬180 16x ¬180 x ¬11.25 3x 3(11.25) or 33.75 6x 6(11.25) or 67.5 7x 7(11.25) or 78.75 Because the angles are all less than 90°, the triangle is acute.

S P

F

H Proof: Statements

Reasons

1. TS S F F H H T 2. TSF, SFH, FHT, and HTS are right angles.

1. Given

3. STH SFH

3. All rt. are .

4. STH SFH

4. SAS

5. SHT SHF

5. CPCTC

2. Given

Page 206 Maintain Your Skills 32. ACB DCE 33. WXZ YXZ 34. LMP NPM 35. m2 78 36. m3 m2 ¬180 m3 78 ¬180 m3 ¬102 37. m4 m5 ¬90 m5 ¬90 m4 m4 m3 56 ¬180 m4 102 56 ¬180 m4 ¬22 m5 ¬90 m4 ¬90 22 or 68 38. m4 m3 56 ¬180 m4 102 56 ¬180 m4 ¬22 39. m1 m2 43 ¬180 m1 78 43 ¬180 m1 ¬59 40. m6 m5 78 ¬180 m6 68 78 ¬180 m6 ¬34

28. Given: D E F B , A E F C , A E D B , C F D B Prove: ABD CDB A B F E D C Plan: First use SAS to show that ADE CBF. Next use CPCTC and Reflexive Property for segments to show ABD CDB. Proof: Statements

Reasons

1. D E F B , A E F C

1. Given

2. A E D B , C F D B

2. Given

3. AED is a right angle. 3. lines form right . CFB is a right angle. 4. AED CFB 5. ADE CBF

4. All right angles are . 5. SAS

6. A D B C

6. CPCTC

7. D B D B

7. Reflexive Property for Segments

8. CBD ADB

8. CPCTC

9. ABD CDB

9. SAS

1.3 0.3 41. rate of change 21 1

0.3 1.1 42. rate of change 32 1.4 43. There is a steeper rate of decline from the second quarter to the third. bisects B 44. B E , since AE C bisects ABC 45. CBD, since BD 46. BDA, since BDC is a right angle and forms a linear pair with BDA 47. C D , since BD bisects A C

29. Sample answer: The properties of congruent triangles help land surveyors double check measurements. Answers should include the following. • If each pair of corresponding angles and sides are congruent, the triangles are congruent by definition. If two pairs of corresponding sides and the included angle are congruent, the triangles are congruent by SAS. If each pair of corresponding sides are congruent, the triangles are congruent by SSS. • Sample answer: Architects also use congruent triangles when designing buildings.

Chapter 4

4-5 Page 207

Proving Congruence—ASA, AAS Construction

5. JKL ABC

Page 208 Geometry Activity 1. They are congruent. 2. The triangles are congruent.

100

Page 210

7. Given: E K, DGH DHG, E G K H Prove: EGD KHD


1. Two triangles can have corresponding congruent angles without corresponding congruent sides. A D, B E, and C F. However, B A

D E , so ABC

DEF. B E A C D

D

E G H K Proof: Since EGD and DGH are linear pairs, the angles are supplementary. Likewise, KHD and DHG are supplementary. We are given that DGH DHG. Angles supplementary to congruent angles are congruent so EGD KHD. Since we are given that E K and G E K H , EGD KHD by ASA. 8. This cannot be determined. The information given cannot be used with any of the triangle congruence postulates, theorems or the definition of congruent triangles. By construction, two different triangles can be shown with the given information. Therefore, it cannot be determined if SRT MKL.

F

2. Sample answer: In ABC, A B is the included side of A and B. C A

B

3. AAS can be proven using the Third Angle Theorem. Postulates are accepted as true without proof. G H 4. Given: G H K J , G K H J Prove: GJK JGH K

J

5.5

Proof:

5.5

49

GH || KJ

GK || HJ

Given

Given

HGJ

KJG

Alt. int.

are .

KGJ

Pages 211–213

HJG

Alt. int.

GJK

7

Practice and Apply

9. Given: EF G H , F E G H Prove: E K K H

are .

JGH

F E K

ASA

GJ

H G

GJ

Proof:

Reflexive Property

EF || GH

5. Given: X W Y Z , X Z Prove: WXY YZW

X

Given

Y

E Z

Vert.

XW || YZ

X

Given

XWY Alt. int.

are .

GKH

Proof:

are .

EK

DE J K 10. Given: K D bisects J E . Prove: EGD JGK

WY

Reflexive Property

WXY

HKG

AAS

KH

CPCTC

Given

WY

EKF

EKF are .

Z

ZYW

GH Given

H

Alt. int.

W

EF

J D G

K

YZW E

AAS

6. Given: QS bisects RST; R T. Prove: QRS QTS

Proof: R

DK bisects JE. Given

DE || JK

S

Q

Given

E

T

Alt. int.

Proof: We are given that R T and Q S bisects RST, so by definition of angle bisector, RSQ TSQ. By the Reflexive Property, S Q Q S . QRS QTS by AAS.

DGE Vert.

101

EG

GJ

Def. of seg. bisector

J are .

KGJ

EGD

JGK

ASA

are .

Chapter 4

11. Given: V S, T V Q S Prove: V R S R

Proof: MN

S

T 2

1

MN

R

PQ

Def. of

MN

NP

NP

PQ

NP

Addition Prop.

S QS

1

Given

2 Vert.

TRV

MP

are .

NQ

MN NP MP NP PQ NQ Seg. Addition Post.

QRS MP

NQ

Def. of

VR

NP

Reflexive Prop.

Substitution

AAS

seg.

SR

CPCTC

MLP

12. Given: EJ F K , J G K H F E G H Prove: EJG FKH

J

K

QLN

M 2

ASA

Q 3

Given

E

F

G

T . 14. Given: Z is the midpoint of C Y C T E Prove: Y Z E Z E C

H

Proof: EF

seg.

Q

V Proof: V TV

PQ

Given

GH

Z

Given

EF

T Proof:

GH Def. of

seg.

FG

FG

EF

GH

FG

Addition Prop.

FG

Y CY || TE

Z is the midpoint of CT.

Reflexive Prop.

Given

Given

EG

FH

Substitution

EG

FH

Def. of

EJG

seg.

EF FG EG FG GH FH

TZ

Seg. Addition Post.

Midpt. Th.

FKH

Corr.

Alt. int.

YZ

KFH KHF

are .

YZC

15. Given: NOM POR, M N M R , R P M R , M N P R Prove: M O O R

L

1

N

2

EZ

CPCTC

are .

13. Given: MN P Q , M Q 2 3 Prove: MLP QLN M

YCT CYE

AAS

Given

JEG JGE

CZ EZT

EJ || FK, JG || KH

ASA

ETC TEY

3

M

O

R

Proof: Since N M M R and P R M R , M and R are right angles. M R because all right angles are congruent. We know that NOM POR and N M P R . By AAS, NMO PRO. M O O R by CPCTC. 16. Given: D L bisects B N . B D XLN XDB Prove: L N D B X

4

P

P

N

Q

L

N

Proof: Since D L bisects B N , B X X N . XLN XDB. LXN DXB because vertical angles are congruent. LXN DXB by AAS. L N D B by CPCTC.

Chapter 4

102

17. Given: F J, E H EC G H Prove: E F H J

F H

G E

4. P P


5. IPK TPB

5. AAS

C 21. Explore: We are given the measurement of one side of each triangle. We need to determine whether two triangles are congruent. Plan: C D G H , because the segments have the same measure. CFD HFG because vertical angles are congruent. Since F is the midpoint of G D , D F F G . Solve: We are given information about side-sideangle (SSA). This is not a method to prove two triangles congruent. Examine: Use a compass, protractor, and ruler to draw a triangle with the given measurements. For simplicity of measurement, use 1 inch instead of 4 feet and 2 inches instead of 8 feet, so the measurements of the construction and those of the garden will be proportional.

J Proof: We are given that F J, E H, and E C G H . By the Reflexive Property, G C C G . Segment addition results in EG EC CG and CH CG GH. By the definition of congruence, EC GH and CG CG. Substitute to find EG CH. By AAS, EFG HJC. By CPCTC, E F H J . 18. Given: TX S Y X T TXY TSY Prove: TSY YXT S Y Proof: Since T X S Y , YTX TYS by Alternate Interior Angles Theorem. T Y T Y by the Reflexive Property. Given TXY TSY, TSY YXT by AAS. 19. Given: MYT NYT M MTY NTY Prove: RYM RYN R T Y

1 in.

N

Proof:

29 2 in.

Statements

Reasons

1. MYT NYT, MTY NTY

1. Given

T Y T , R Y R Y 2. Y


3. MYT NYT

3. ASA

4. MY N Y 5. RYM and MYT are a linear pair; RYN and NYT are a linear pair

4. CPCTC

• Draw a segment 2 inches long. • At one end, draw an angle of 29°. Extend the line longer than 2 inches. • At the other end of the segment, draw an arc with a radius of 1 inch such that it intersects the line. Notice that there are two possible segments that could determine the triangle. It cannot be determined whether CFD HFG. The information given does not lead to a unique triangle. 22. Explore: We need to determine whether two triangles are congruent. Plan: Since F is the midpoint of D G , D F F G . F is also the midpoint of C H , so C F F H . Since G D C H , D F C F and F G F H . CFD HFG because vertical angles are congruent. Solve: CFD HFG by SAS. Examine: The corresponding sides and angles used to determine the triangles are congruent by SAS are D F F G , CFD HFG, and C F F H . 23. Explore: We need to determine whether two triangles are congruent. Plan: Since N is the midpoint of J L , J N N L . JNK LNK because perpendicular lines form right angles and right angles are congruent. By the Reflexive Property, K N K N . Solve: JKN LKN by SAS. Examine: The corresponding sides and angles used to determine the triangles are congruent by SAS are J N N L, JNK LNK, and K N K N.


6. Supplement 6. RYM and MYT are supplementary and RYN Theorem and NYT are supplementary. 7. RYM RYN

7. suppl. to are .

8. RYM RYN

8. SAS

20. Given: BMI KMT B IP P T Prove: IPK TPB

I P M T K

Proof: Statements

Reasons

1. BMI KMT

1. Given

2. B K

2. CPCTC

3. IP P T

3. Given

103

Chapter 4

x 32. A; x percent of 10,000 ¬ 10 0 (10,000) 1 percent of x percent of 10,000 1 x ¬ 100 100 (10,000)

24. Explore: We are given the measurements of one side and one angle of each triangle. We need to determine whether the two triangles are congruent. Plan: It is given that J M L M and NJM NLM. By the Reflexive Property, N M N M . Solve: We are given information about side-sideangle (SSA). This is not a method to prove two triangles congruent. Examine: Use a compass, protractor, and ruler to draw a triangle with the given measurements. For simplicity of measurement, we will use centimeters instead of feet, so the measurements of the construction and those of the kite will be proportional. • Draw a segment 2.7 centimeters long. • At one end, draw an angle of 68°. Extend the line to exactly 2 centimeters. • At the other end of the segment, draw a seg-ment that intersects the 2 centimeter segment at any place other than either of its endpoints. Because no information is known about the length of the segment that determines the triangle, an infinite number of triangles are possible. It cannot be determined whetherJNM LNM. The information given does not lead to a unique triangle.

x ¬ (10,000) 10,000

¬x

Page 213


33. Given: BA D E , A D B E Prove: BEA DAE

B

D C

A

E

Proof: DA

BE

Given

BA

DE

BEA

Given

AE

DAE

SSS

AE

Reflexive Prop.

XZ W Y , 34. Given: W Z X bisects W Y . Prove: WZX YZX

Z

2 cm

X

Y

Proof: 68˚

J

2.7 cm

XZ

M

25. VNR, AAS or ASA 26. VMN, ASA or AAS 27. MIN, SAS 28. RMI, AAS or ASA 29. Since Aiko is perpendicular to the ground, two right angles are formed and right angles are congruent. The angles of sight are the same and her height is the same for each triangle. The triangles are congruent by ASA. By CPCTC, the distances are the same. The method is valid. 30. Sample answer: The triangular trusses support the structure. Answers should include the following. • To determine whether two triangles are congruent, information is needed about consecutive side-angle-side, side-side-side, angle-side-angle, angle-angle-side, or about each angle and each side. • Triangles that are congruent will support weight better because the pressure will be evenly divided. 31. D; mB mBAC mBCA ¬180 76 mBAC mBCA ¬180 mBAC mBCA ¬104

WZX and YZX are rt . Def. of ⊥ lines.

WZX All rt.

XZ

YZX are .

XZ

XZ bisects WY. Given

WZ

ZY

Def. of seg. bisector

WZX

YZX

SAS

Reflexive Prop.

35.

D A bisects BAC, so mDAC ¬1 2 mBAC. 1 C D bisects BCA, so mDCA ¬2mBCA. 1 mDAC mDCA ¬1 2 mBAC 2 mBCA ¬1 2 (mBAC mBCA) ¬1 2 (104) or 52

mADC mDAC mDCA ¬180 mADC 52 ¬180 mADC ¬128 Chapter 4

WY Given

104

RS ¬[1 (2)]2 (1 2)2 ¬1 1 or 2 2 [2)] RS ¬(1 ) 21 (2 ¬1 1 or 2 ST ¬[2 (1)]2 (1 1)2 ¬1 0 or 1 2 [1)] ST ¬(2 ) 11 (2 ¬1 0 or 1 RT ¬[2 (2)]2 (1 2)2 ¬0 1 or 1 2 [2)] RT ¬(2 ) 21 (2 ¬0 1 or 1 2 [2)] RT ¬(2 ) 21 (2 ¬0 1 or 1 Each pair of corresponding sides has the same measure, so they are congruent. Use a protractor to confirm that the corresponding angles are congruent. Therefore, RST RST. RST is a turn of RST.

36.

37. 38. 39. 40. 41.

8. Given: ABC and XYZ are right triangles. A and X are right angles. C B Y Z B Y Prove: ABC XYZ C Z

MP ¬[1 (3)]2 (1 1)2 ¬4 0 or 2 2 (1 MP ¬(0 ) 2 1)2 ¬4 0 or 2 MN ¬[3 (3)]2 (4 1)2 ¬0 9 or 3 2 (4 MN ¬(2 ) 2 1)2 ¬0 9 or 3 NP ¬[1 (3)]2 (1 4)2 ¬4 9 or 13 2 (4 NP ¬(2 ) 0 1)2 ¬4 9 or 13 Each pair of corresponding sides has the same measure, so they are congruent. Use a protractor to confirm that the corresponding angles are congruent. Therefore, MPN MPN. MPN is a flip of MPN. If people are happy, then they rarely correct their faults. If a person is a champion, then he or she is afraid of losing. Since two sides are marked congruent, the triangle is isosceles. Since three sides are marked congruent, the triangle is equilateral. Since two sides are marked congruent, the triangle is isosceles.

A B X Y Proof: We are given that ABC and XZY are right triangles with right angles A and X, C B Y Z , and B Y. Since all right angles are congruent, A X. Therefore, ABC XYZ by AAS. 9. Case 1: Given: ABC and DEF are right triangles. C A D F C F Prove: ABC DEF F

A

B D

E

Proof: It is given that ABC are DEF are right triangles, A C D F , C F. By the definition of right triangles, A and D are right angles. Thus, A D since all right angles are congruent. ABC DEF by ASA. Case 2: Given: ABC and DEF are right triangles. C A D F B E Prove: ABC DEF C F

Pages 214–215 Geometry Activity: Congruence in Right Triangles 1. yes; a. SAS, b. ASA, c. AAS 2a. LL 2b. LA 2c. HA 3. None; two pairs of legs congruent is sufficient for proving right triangles congruent. 4. yes 5. yes 6. SSA is a valid test of congruence for right triangles. 7. Given: DEF and RST are right triangles. E and S are right angles. F E S T D E S R Prove: DEF RST F

C

A B D E Proof: If is given that ABC and DEF are right triangles, A C D F , and B E. By the definition of right triangle, A and D are right angles. Thus, A D since all right angles are congruent. ABC DEF by AAS. 10. Given: M L M K , J K K M , J L Prove: J M K L M L J

K

Proof:

T

D E R S Proof: We are given that E F S T , E D S R , and E and S are right angles. Since all right angles are congruent, E S. Therefore, by SAS, DEF RST.

105

Statements

Reasons

1. ML M K , J K K M , J L

1. Given

2. LMK and JKM are rt.

2. lines form rt. .

3. LMK and JKM are rt. s

3. Def. of rt.

4. M K M K


5. LMK JKM

5. LA

6. J M K L

6. CPCTC

Chapter 4

11. Given: JK K M , M J K L L M J K Prove: M L J K

M J

7. Given: CTE is isosceles with vertex C. mT 60 C Prove: CTE is equilateral.

L

K

Proof: Reasons

Statements

Reasons

1. CTE is isosceles with vertex C.

1. Given

T C E 2. C

5. mT 60

2. Def. of isosceles triangle 3. Isosceles Triangle Theorem 4. Def. of 5. Given

6. HL

6. mE 60

6. Substitution

7. CPCTC

7. mC + mE + mT 7. Angle Sum Theorem 180 8. mC 60 60 180 8. Substitution

1. JK K M , J M K L , 1. Given L M J K 2. lines form rt. 2. JKM is a rt. 3. K M M L

3. E T

4. LMK is a rt. 5. M K M K 6. JMK LMK 7. M L J K

Page 216

3. Perpendicular Transversal Th. 4. lines form rt. 5. Reflexive Property

4. mE mT

Isosceles Triangles

9. mC 60

11. CTE is equilateral. 11. Equiangular s are equilateral.

Geometry Activity: Isosceles Triangles

8. A; Read the Test Item PQS is isosceles with base P S . Likewise, QRS is isosceles with base Q S . Solve the Test Item Step 1 The base angles of QRS are congruent. Let x mRSQ mRQS. mPRS mRSQ mRQS ¬180 72 x x ¬180 72 2x ¬180 2x ¬108 x ¬54 So, mRSQ mRQS 54. Step 2 RQS and PQS form a linear pair. Solve for mPQS. mRQS mPQS ¬180 54 mPQS ¬180 mPQS ¬126 Step 3 The base angles of PQS are congruent. Let y represent mQPS and mPSQ. mPQS mQPS mPSQ ¬180 126 y y ¬180 126 2y ¬180 2y ¬54 y ¬27 The measure of QPS is 27. Choice A is correct.


1. The measure of only one angle must be given in an isosceles triangle to determine the measures of the other two angles. 2. W X Z X ; W Z 3. Sample answer: Draw a line segment. Set your compass to the length of the line segment and draw an arc from each endpoint. Draw segments from the intersection of the arcs to each endpoint. 4. ADH is opposite A H and AHD is opposite A D , so ADH AHD. 5. B H is opposite BDH and B D is opposite BHD, so B H B D . 6. Each angle of an equilateral triangle measures 60°. mF ¬3x 4 60 ¬3x 4 56 ¬3x 56 3 ¬x mG ¬6y 60 ¬6y 10 ¬y mH ¬19z 3 60 ¬19z 3 57 ¬19z 3 ¬z

Chapter 4

9. Subtraction

10. CTE is equiangular. 10. Def. of equiangular

1. A B 2. They are congruent. 3. They are congruent.

Page 219

E

Proof:

Statements

4-6

T 60

Pages 219–221

Practice and Apply

9. LRT is opposite L T and LTR is opposite L R , so LRT LTR. 10. LXW is opposite L W and LWX is opposite L X , so LXW LWX. 11. LSQ is opposite Q L and LQS is opposite S L , so LSQ LQS.

106

12. LX is opposite LYX and L Y is opposite LXY, so X L L Y . 13. L S is opposite LRS and L R is opposite LSR, so S L L R . 14. L Y is opposite LWY and L W is opposite LYW, Y L W . so L 15. The base angles of an isosceles triangle are congruent. So LNM MLN. From the figure, mMLN 20. So mLNM 20. 16. mLNM mMLN mM ¬180 20 20 mM ¬180 mM ¬140 17. The base angles of an isosceles triangle are congruent, so mLKN ¬mLNK. mLKN mLNK mKLN ¬180 mLKN mLKN 18 ¬180 2mLKN ¬162 mLKN ¬81 18. mJKN ¬mJKL mLKN 130 ¬mJKL 81 49 ¬mJKL mJKL mJLK mJ ¬180 49 25 mJ ¬180 mJ ¬106 19. The base angles of DFG are congruent, so DFG D. mDFG mD 28 20. mDGF mD mDFG ¬180 28 28 mDGF ¬180 mDGF ¬124 21. FGH and DGF are a linear pair. mDGF mFGH ¬180 124 mFGH ¬180 mFGH ¬56 22. The base angles of FGH are congruent, so FGH H. From Exercise 21, mFGH ¬56. mFGH mH mGFH ¬180 56 56 mGFH ¬180 mGFH ¬68 23. MLP is isosceles with base M P . JMP is isosceles with base J P . Step 1 The base angles of MLP are congruent. Let x represent mPML and mMPL. mPML mMPL mPLJ ¬180 x x 34 ¬180 2x 34 ¬180 2x ¬146 x ¬73 So, mPML mMPL 73. Step 2 PML and JMP form a linear pair. Solve for mJMP. mPML mJMP ¬180 73 mJMP ¬180 mJMP ¬107 Step 3 The base angles of JMP are congruent. Let y represent mJ and mJPM. mJPM mJ mJMP ¬180 y y 107 ¬180 2y 107 ¬180 2y ¬73 y ¬36.5 So, mJPM mJ 36.5.

24. MLP is isosceles with base M P , JMP is isosceles with base J P . Step 1 The base angles of MLP are congruent. Let x represent mPML and mMPL. mPML mMPL mPLJ ¬180 x x 58 ¬180 2x 58 ¬180 2x ¬122 x ¬61 So, mPML mMPL 61. Step 2 PML and JMP form a linear pair. Solve for mJMP. mPML mJMP ¬180 61 mJMP ¬180 mJMP ¬119 Step 3 The base angles of JMP are congruent. Let y represent mPJL and mJPM. mJPM mPJL mJMP ¬180 y y 119 ¬180 2y 119 ¬180 2y ¬61 y ¬30.5 So, mJPM mPJL 30.5. 25. GKH is isosceles with base H K . JKH is isosceles with base H J . Step 1 The base angles of GKH are congruent. Let x represent mGHK and mGKH. mHGK mGHK mGKH ¬180 28 x x ¬180 2x ¬152 x ¬76 So, mGHK mGKH 76. Step 2 GKH and HKJ form a linear pair. Solve for mHKJ. mGKH mHKJ ¬180 76 mHKJ ¬180 mHKJ ¬104 Step 3 The base angles of JKH are congruent. Let x represent mHJK and mJHK. mHJK mJHK mHKJ ¬180 x x 104 ¬180 2x 104 ¬180 2x ¬76 x ¬38 So, mHJK mJHK 38. 26. GKH is isosceles with base H K . Step 1 The base angles of GKH are congruent. Let x represent mGHK and mGKH. mHGK mGHK mGKH ¬180 42 x x ¬180 42 2x ¬180 2x ¬138 x ¬69 So, mGHK mGKH 69. Step 2 GKH and HKJ form a linear pair. Solve for mHKJ. mGKH mHKJ ¬180 69 mHKJ ¬180 mHKJ ¬111

107

Chapter 4

27. LMN is equilateral, so L M M N L N . M P bisects L N , so M P bisects LMN. LMN is equilateral, hence equiangular. So mLMN mMLP 60 and mPML 30. LM ¬MN 3x 1 ¬4x 2 3 ¬x mPLM mPML mMPL ¬180 60 30 5y ¬180 90 5y ¬180 5y ¬180 y ¬18 28. LM 3x 1 3(3) 1 or 10 LM MN LN, so all sides have measure 10. 29. Given: XKF is equilateral. X J X bisects X. Prove: J is the midpoint of K F . 1

K

10. mLNM mLNP 180 11. 2mLNM 180

10. Sum of measures of a linear pair of angles is 180 11. Substitution

12. mLNM 90

12. Division

13. LNM is a right angle.

13. Definition of right angle

14. L N M P

14. Definition of perpendicular

31. Case I: Given: ABC is an equilateral triangle. Prove: ABC is an equiangular triangle. B

A Proof:

2

J

C

F

Proof:

Statements

Reasons

Statements

Reasons

1. ABC is an equilateral triangle.

1. Given

1. XKF is equilateral.

1. Given

2. A B A C B C

2. Def. of equilateral

2. K X F X

3. A B, B C, A C 4. A B C

3. Isosceles Triangle Theorem 4. Substitution

4. X J bisects X

2. Definition of equilateral 3. Isosceles Triangle Theorem 4. Given

5. KXJ FXJ

5. Def. of bisector

6. KXJ FXJ

6. ASA

7. K J J F

7. CPCTC

3. 1 2

5. ABC is an 5. Def. of equiangular equiangular triangle. Case II: Given: ABC is an equiangular triangle. Prove: ABC is an equilateral triangle. B

8. J is the midpoint of K F . 8. Def. of midpoint 30. Given: MLP is isosceles. N is the midpoint of M P . Prove: L N M P

L A

M

N

Statements

P

Reasons

1. MLP is isosceles. 1. Given 2. M L L P

2. Definition of isosceles

3. M P

3. Isosceles Triangle Theorem 4. Given

4. N is the midpoint of M P . 5. M N N P 6. MNL PNL

5. Midpoint Theorem

7. LNM LNP

7. CPCTC

8. mLNM mLNP

8. Congruent angles have equal measures.

6. SAS

9. LNM and LNP 9. Definition of linear pair are a linear pair

Chapter 4

Reasons

1. Given 1. ABC is an equiangular triangle.

Proof: Statements

C Proof:

108

2. A B C

2. Def. of equiangular

3. AB A C , A B B C , C A B C

3. Conv. of Isos. Th.

B A C B C 4. A

4. Substitution

5. ABC is an equilateral triangle.


32. Given: MNO is an equilateral triangle. Prove: mM mN mO 60

36. The triangle is isosceles with base angles having measure 3x 8. (3x 8) (3x 8) (2x 20) ¬180 8x 36 ¬180 8x ¬144 x ¬18 37. The triangle on the bottom half of the figure is isosceles. The base angles are congruent. 2x 25 ¬x 5 x 25 ¬5 x ¬30 38. There are two sets of 12 isosceles triangles. One black set forms a circle with their bases on the outside of the circle. Another black set encircles a circle in the middle.

O

M

N

Proof: Statements

Reasons

1. MNO is an equilateral triangle.

1. Given

2. M N M O N O


3. M N O

3. Isosceles Thm.

4. mM mN mO 4. Def. of 5. mM mN mO 180 6. 3mM 180


7. mM 60

7. Division Property

8. mM mN mO 60

8. Substitution

6. Substitution

33. Given: ABC A C Prove: A B C B

39. The triangles in each set appear to be acute. 40. DCE is equilateral, hence equiangular so mCDE mDEC mDCE 60. Then we know, mACB mDCE so mACB 60 and mFCG mDCE so mFCG 60. This means that in isosceles ABC, BAC and ABC are the congruent base angles, so mABC mBAC 42. Also, in isosceles FCG, CFG and FGC are the congruent base angles, so mCFG mFGC 77. mACB mABC mBAC ¬180 mACB 42 42 ¬180 mACB ¬96 mFCG mCFG mFGC ¬180 mFCG 77 77 ¬180 mFCG ¬26 So m3 26 mCFD mCFG ¬180 mCFD 77 ¬180 mCFD ¬103 mCGF mCGE ¬180 77 mCGE ¬180 mCGE ¬103 m2 mCDF mCFD ¬180 m2 60 103 ¬180 m2 ¬17 m4 mCEG mCGE ¬180 m4 60 103 ¬180 m4 ¬17 CDA CEB by AAS Postulate So 1 5 2m1 2(17) 26 ¬mACB 2m1 60 ¬96 2m1 ¬36 m1 ¬18 So, m1 18, m2 17, m3 26, m4 17, and m5 18. 41. Sample answer: Artists use angles, lines, and shapes to create visual images. Answers should include the following. • Rectangle, squares, rhombi, and other polygons are used in many works of art. • There are two rows of isosceles triangles in the painting. One row has three congruent isosceles triangles. The other row has six congruent isosceles triangles.

B

A

D

C

Proof: Statements

Reasons

1. Let BD bisect ABC. 1. Protractor Postulate 2. ABD CBD

2. Def. of bisector

3. A C

3. Given

4. B D B D


5. ABD CBD

5. AAS

6. A B C B

6. CPCTC

34. The minimum requirement is that two angles measure 60°. 35. The front face of the figure has two congruent angles and one angle of measure 60. Let y represent the measure of each of the congruent angles. y y 60 ¬180 2y 60 ¬180 2y ¬120 y ¬60 Therefore all angles have measure 60, so the triangle is equiangular and equilateral. All sides have length 2x 5, in particular the edge between the front face and the side face showing. Because the side face has two congruent base angles it is isosceles and the sides opposite the congruent angles are congruent. 2x 5 ¬3x 13 2x 18 ¬3x 18 ¬x

109

Chapter 4

42. A; mZXY mPYZ ¬90 mZXY 26 ¬90 mZXY ¬64 PYZ is isosceles since YP YZ, so mYPZ mYZP. mYPZ mYZP mPYZ ¬180 2(mYPZ) 26 ¬180 2(mYPZ) ¬154 mYPZ ¬77 mXPZ mYPZ ¬180 mXPZ 77 ¬180 mXPZ ¬103 mXZP mXPZ mPXZ ¬180 mXZP 103 64 ¬180 mXZP ¬13

2 [1)] 47. QR ¬(5 ) 1 (52 ¬16 6 3 or 52 EG ¬[1 (4)]2 [2)] (32 ¬9 25 or 34 2 (0 RS ¬(4 ) 5 1)2 ¬1 1 or 2 2 GH ¬[2 1)] ( (1 2)2 ¬9 1 or 10 2 [0)] QS ¬(4 ) 1 (52 ¬9 25 or 34 2 EH ¬[2 4)] ( [1 (3)]2 ¬36 6 1 or 52 The corresponding sides are not congruent so QRS is not congruent to EGH. 48. a b a and b

x1 x2 y1 y2 3 9 5 13 43. D; , 2, 2 2 2

Page 221

12 1 8 2 , 2 or (6, 9)


44. Given: N D, G I, A N S D Prove: ANG SDI

G

49.

S A D

I

T

F

F

F

T

F

F

F

F p q p or q

p

q

T

T

F

F

F

T

F

F

T

T

F

T

T

F

T

F

F

T

T

T

m k and m

R

V

50.

S U

T

Proof: We are given that V R R S , U T S U and S R U S . Perpendicular lines form four right angles so R and U are right angles. R U because all right angles are congruent. RSV UST since vertical angles are congruent. Therefore, VRS TUS by ASA.

51.

2 46. QR ¬[1 3)] ( (2 1)2 ¬16 1 or 17 2 [2)] EG ¬(2 ) 63 (2 ¬16 1 or 17 RS ¬(1 1)2 (2 2)2 ¬4 16 or 20 2 [1)] GH ¬(4 ) 2 (32 ¬4 16 or 20 QS ¬[1 (3)]22 ( 1)2 ¬4 9 or 13 2 [1)] EH ¬(4 ) 6 (22 ¬4 9 or 13 Each pair of corresponding sides has the same measure so they are congruent. QRS EGH by SSS.

Chapter 4

T

T

N

Proof: We are given N D and G I. By the Third Angle Theorem, A S. We are also given A N S D . ANG SDI by ASA. 45. Given: VR R S , T U S U , S R U S Prove: VRS TUS

T

k

m

T

T

F

F

T

F

T

T

F

T

F

F

F

F

T

F

y y or z

y

z

T

T

F

T

T

F

F

F

F

T

T

T

F

F

T

T

x1 x2 y1 y2 2 7 15 9 52. , 2, 2 2 2

(4.5, 12)

x1 x2 y1 y2 4 2 6 (12) 53. , 2, 2 2 2

(1, 3)

x1 x2 y1 y2 3 7.5 2.5 4 54. , 2, 2 2 2

(5.25, 3.25)

110

Page 221 1. JM

2. Sample answer:

Practice Quiz 2

¬[2 (4)]2 (6 5)2

y

¬4 1 or 5 BD ¬[4 (3)]22 [4)] (2 ¬1 4 or 5 ML ¬[1 (2)]2 (1 6)2 ¬1 25 or 26 2 DG ¬[1 4)] ( [1)] (22 ¬25 1 or 26 JL ¬[1 (4)]2 (1 5)2 ¬9 16 or 5 2 BG ¬[1 3)] ( [1)] (42 ¬16 9 or 5 Each pair of corresponding sides has the same measure so they are congruent. JML BDG by SSS. 2. Given: A H, AEJ HJE Prove: A J E H E A

J

C(0, b)

3. • Use the origin as vertex F of the triangle. • Place the base of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since H is on the x-axis, its y-coordinate is 0. Its x-coordinate is 2b because the base of the triangle is 2b units long. • Since FGH is isosceles, the x-coordinate of G is halfway between 0 and 2b or b. We cannot determine the y-coordinate in terms of b, so call it c. y

G(b, c)

H F(0, 0) H(2b, 0) x

Proof: Statements

Reasons

1. A H, AEJ HJE

1. Given

J E J 2. E 3. AEJ HJE

2. Reflexive Property 3. AAS

4. A J E H

4. CPCTC

4. • Use the origin as vertex C of the triangle. • Place side C D of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since D is on the x-axis, its y-coordinate is 0. Its x-coordinate is a because each side of the triangle is a units long. • Since CDE is equilateral, the x-coordinate of E is halfway between 0 and a, or a 2. We cannot determine the y-coordinate in terms of a, so call it b.

3. From the figure, W X X Y so the angles opposite these sides are congruent. That is, mXWY mXYW. mXYW mXYZ ¬180 mXYW 128 ¬180 mXYW ¬52 So, mXWY 52. 4. From Question 3, mXWY 52. mWXY mXWY mXYW ¬180 mWXY 52 52 ¬180 mWXY ¬76 5. XYZ is isosceles with YZX YXZ. mYZX mYXZ mXYZ ¬180 2(mYZX) 128 ¬180 2(mYZX) ¬52 mYZX ¬26

4-7

B(a, 0) x

A(0, 0)

y

E

a

2 ,b

C(0, 0) D (a, 0) x 5. Vertex P is on the y-axis, so its x-coordinate is 0. R is a right angle and R Q has length a, but there is no other information given to determine the y-coordinate of P, so let the y-coordinate be b. So, the coordinates of P are (0, b). 6. Vertex Q is on the x-axis, so its y-coordinate is 0. PQN is equilateral and the y-axis bisects side N Q . The x-coordinate of N is 2a, so the x-coordinate of Q is 2a. So, the coordinates of Q are (2a, 0). 7. Vertex N is on the y-axis and no information is given to determine its y-coordinate, so the coordinates of N are (0, b) for some b. Vertex Q is on the x-axis, so its y-coordinate is 0. NRQ is isosceles and the y-axis bisects its base R Q . The x-coordinate of R is a, so the x-coordinate of Q is a. So, the coordinates of Q are (a, 0).

Triangles and Coordinate Proof

Page 224 Check for Understanding 1. Place one vertex at the origin, place one side of the triangle on the positive x-axis. Label the coordinates with expressions that will simplify the computations.

111

Chapter 4

8. Given: ABC is a right y B(0, 2b) triangle with hypotenuse B C. M M is the midpoint of B C. Prove: M is equidistant A(0, 0) C(2c, 0) x from the vertices. Proof: The coordinates of M, the midpoint of B C , c (c, b). will be 22 , 22b

• Since MNP is equilateral, the x-coordinate of P is halfway between 0 and 2a, or a. We cannot determine the y-coordinate in terms of a, so call it b. y

9. Given: ABC Prove: ABC is isosceles.

y

N (2a, 0) x

M (0, 0)

The distance from M to each of the vertices can be found using the Distance Formula. 2 (b 2 b2 MB (c ) 0 2b)2 c 2 ( 2 b2 MC (c c) 2b 0)2 c 2 (b 2 b2 MA (c ) 0 0)2 c Thus, MB MC MA, and M is equidistant from the vertices.

P (a, b)

12. • Use the origin as vertex L of the triangle. • Place leg L M of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since M is on the x-axis, its y-coordinate is 0. Its x-coordinate is c because each leg is c units long. • Since J is on the y-axis, its x-coordinate is 0. Its y-coordinate is c because each leg is c units long.

B(2, 8)

y

J(0, c)

A(0, 0)

C (4, 0)

13. • Use the origin as vertex W of the triangle. • Place side W Z of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since Z is on the x-axis, its y-coordinate is 0. Its x-coordinate is b 2 because each side of the b units long. triangle is 1 2 • Since WXZ is equilateral, the x-coordinate of X b is halfway between 0 and b 2, or 4. We cannot determine the y-coordinate in terms of b, so call it c.

Proof: Use the Distance Formula to find AB and BC. 2 (8 AB (2 ) 0 0)2 4 64 or 68 2 BC (4 ) 2 (0 8)2 4 64 or 68 Since AB BC, A B B C . Since the legs are congruent, ABC is isosceles.

Pages 224–226 Practice and Apply 10. • Use the origin as vertex Q of the triangle. • Place the base of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since R is on the x-axis, its y-coordinate is 0. Its x-coordinate is b because the base Q R is b units long. • Since QRT is isosceles, the x-coordinate of T is halfway between 0 and b or b 2. We cannot determine the y-coordinate in terms of b, so call it c. y

Q (0, 0)

y

X(1–4b,c)

Z (1–2b, 0) x

W(0, 0)

14. • Use the origin as vertex P of the triangle. • Place side P W of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since W is on the x-axis, its y-coordinate is 0. Its x-coordinate is a b because the base is a b units long. • Since PWY is isosceles, the x-coordinate of Y is a b halfway between 0 and a b or 2 . We cannot determine the y-coordinate in terms of a and b, so call it c.

T (b–2, c)

R(b, 0) x

11. • Use the origin as vertex M of the triangle. • Place side M N of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since N is on the x-axis, its y-coordinate is 0. Its x-coordinate is 2a because each side of the triangle is 2a units long.

Chapter 4

M (c, 0) x

L(0, 0)

x

y

P(0, 0)

112

Y (a 2 b , c)

W(a b, 0) x

24. Since NPQ is right isosceles, N Q P Q and Q N P Q . Then Q and P have the same x-coordinate, so the x-coordinate of Q is a. Q is on the x-axis, so the coordinates of Q are (a, 0). y 25. Given: isosceles ABC C(2a, 2b) with A C B C R and S are S R midpoints of legs A C and B C . Prove: A S B R A(0, 0) B(4a, 0) x

15. • Use the origin as vertex Y of the triangle. • Place leg Y Z of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since X is on the y-axis, its x-coordinate is 0. Its y-coordinate is b because X Y is b units long. • Since Z is on the x-axis, its y-coordinate is 0. Its x-coordinate is 2b because XY b and ZY 2(XY) or 2b. y

X(0, b)

Proof: The coordinates of R are 2a 0 2b 0 2, 2 or (a, b).

Y (0, 0)

4a 2a 0 , 2b 2 The coordinates of S are 2 or (3a, b). BR ¬(4a a)2 ) (0 b2 2 2 ¬(3a) (b)2 or 9a b2 AS ¬(3a 0)2 ) (b 02 2 2 ¬(3a) (b)2 or 9a b2 Since BR AS, A S B R . y 26. Given: isosceles ABC C(a, b) with B C A C R, S, and T are S R midpoints of their respective sides. Prove: RST is isosceles. A(0, 0) T B(2a, 0) x

Z(2b, 0) x

16. Since PQR is equilateral, the x-coordinate of R is halfway between 0 and 2a, or a. So, the coordinates of R are (a, b). 17. Since LPQ is right isosceles, L P P Q and P L P Q . Then Q and P have the same x-coordinate, so the x-coordinate of P is a. P is on the x-axis, so its y-coordinate is 0. The distance from L to P is a units. The distance from P to Q must be the same. So, the coordinates of Q are (a, a) and the coordinates of P are (a, 0). 18. JKN is isosceles, so J K J N . The distance from J to K is 2a units. The distance from J to N must be the same. N is on the y-axis, so the coordinates of N are (0, 2a). 19. CDF is equilateral, so the x-coordinate of F is halfway between 0 and the x-coordinate of D. So the x-coordinate of D is 2b. D is on the x-axis, so the coordinates of D are (2b, 0). 20. BCE is isosceles and the y-axis intersects side C B at its midpoint. The distance from the origin to C is the same as the distance from the origin to B. B is on the x-axis to the left of 0, so the coordinates of B are (a, 0). E is on the y-axis, and we cannot determine the y-coordinate in terms of a, so call it b. The coordinates of E are (0, b). 21. MNP is isosceles and the y-axis intersects side N M at its midpoint. The distance from the origin to M is the same as the distance from the origin to N. N is on the x-axis, so the coordinates of N are (2b, 0). P is on the y-axis, and we cannot determine the y-coordinate in terms of b, so call it c. The coordinates of P are (0, c). 22. JHG is isosceles and the y-axis intersects side JH at its midpoint. The distance from the origin to J is the same as the distance from the origin to H. H is on the x-axis, so the coordinates of H are (b, 0). G is on the y-axis, and we cannot determine the y-coordinate in terms of b, so call it c. The coordinates of G are (0, c). 23. JKL is isosceles, so the x-coordinate of J is halfway between 0 and 2c, or c. We cannot determine the y-coordinate in terms of c, so call it b. The coordinates of J are (c, b).

Proof:

2a 0 a b 3a b Midpoint S is 2, 2 or 2 , 2 . 2a 0 00 Midpoint T is 2, 2 or (a, 0). 2 2 b 0 RT ¬ 2 a2 a 2 b 2 ¬ 2 a2 2 2 ¬ a2 b2 2 2 ST ¬ a 0 32a b2 2 2 ¬ a2 b2 0 b0 a a b Midpoint R is 2 , 2 or 2, 2 .

RT ST and R T S T and RST is isosceles. y 27. Given: ABC C(b, c) S is the midpoint of A C. T is the midpoint of B C. T S Prove: S T A B B(a, 0) x

A(0, 0) Proof:

a b 0 c a b c Midpoint T is 2 , 2 or 2 , 2 .

0 c0 b b c Midpoint S is 2 , 2 or 2, 2 .

Slope of S T

c c 2 2 a b b 2 2

0 or 0. a 2

00 0 B Slope of A a 0 a or 0.

T S and A B have the same slope so S T A B .

113

Chapter 4

28. Given: ABC C. S is the midpoint of A T is the midpoint of B C. AB Prove: ST 1 2

y

32. Given: JCT Prove: JCT is a right triangle.

C(b, c)

y

T

S

J

B(a, 0) x

A(0, 0)

(–500, 300)

a b 0 c a b c Midpoint T is 2, 2 or 2 , 2 . 2 2 a b c c Proof: ST ¬ b 2 2 2 2 0 0 b c c Midpoint S is or b 2 , 2 2, 2 .

2

300 0 3 Proof: The slope of J C 500 0 or 5 . 500 0 5 C The slope of T 300 0 or 3 .

C is the opposite reciprocal of the The slope of T slope of J C . JC T C , so TCJ is a right angle. JCT is a right triangle. 33. Use the Distance Formula to find the distance between J(500, 300) and T(300, 500). 2 JT ¬[300 0)] (50 (500 ) 3002 ¬680,0 00 ¬824.6 The distance between Tami and Juan is 680,0 00 or approximately 824.6 feet. 34. X is at the origin, so place Y(a, b) in the first quadrant. Draw a perpendicular segment from Y to the x-axis, label the intersection point Z. Z has the same x-coordinate as Y, or a. Z is on the x-axis, so the coordinates of Z are (a, 0).

2

2

2 (0 AB ¬(a ) 0 0)2 2 02 ¬a or a ST ¬1 2 AB y 29. Given: ABD, FBD AF 6, BD 3 Prove: ABD FBD

B(3, 4)

A(0, 1) D(3, 1) O

F(6, 1) x

Proof: BD ¬B D by the Reflexive Property. 2 (1 AD ¬(3 ) 0 1)2 9 0 or 3 2 (1 DF ¬(6 ) 3 1)2 9 0 or 3 D D F . Since AD DF, A 2 (4 AB (3 ) 0 1)2 9 9 or 32 2 (1 BF (6 ) 3 4)2 9 9 or 32 Since AB BF, A B B F . ABD FBD by SSS. 30. Given: BPR y B(800, 800) PR 800, BR 800 Prove: BPR is A(1600, 0) an isosceles x right triangle. P(0, 0) R(800, 0)

y

Y (a, b)

O X (0, 0)

Z (a, 0)

x

35. X is at the origin, so place Y(a, b) in the first quadrant. XYZ is isosceles, so place Z on the x-axis so that the x-coordinate of Y is halfway between 0 and the x-coordinate of Z. So, the coordinates of Z are (2a, 0).

Proof: Since PR and BR have the same measure, R P B R . 0 0 The slope of PR 800 0 or 0.

y

800 0 The slope of BR 800 800 , which is undefined.

Y (a, b)

PR B R , so PRB is a right angle. BPR is an isosceles right triangle. 31. Given: BPR, y B(800, 800) BAR PR 800, BR 800, A(1600, 0) RA 800 x Prove: P B B A P(0, 0) R(800, 0)

x O X (0, 0)

Proof: PB (800 0)2 (800 0)2 or 1,280 ,000 2 BA (800 1600)00 (8) 02 or 1,280 ,000 PB BA, so P B B A .

Chapter 4

x

C(0, 0)

0 a2 a a ¬ 2 or 2 ¬

T(300, 500)

114

Z (2a, 0)

36. Sample answer: X is at the origin, so place Y(a, b) in the first quadrant. XYZ is scalene, so place Z on the x-axis so that the x-coordinate c is such that XZ YZ XY. So, the coordinates of Z are (c, 0).

42. Given: isosceles triangle K 2 JKN with vertex N, J K L M Prove: NML is isosceles J

y

1

M 4

N 3

L

Proof: Y (a, b)

x O X (0, 0)

Z (c, 0)

37. AB 4a AC ¬(0 2a)) (2a (2 0)2 2 ¬4a 4a2 or 8a 2 2 CB ¬(0 a) 2(2a 0)2 2 2 2 ¬4a 4a or 8a

1. Given

3. 2 1

3. Isosceles Triangle Theorem 4. Given

7. 4 3

8. L N M N 9. NML is an isosceles triangle.

2. Def. of isosceles triangle

7. Congruence of is transitive. (Statements 3 and 6) 8. If 2 of a are , then the sides opp. those are . 9. Def. of isosceles triangle

43. Given: A D C E , A D C E Prove: ABD EBC A C

39. C; d ¬(3 1)2 2)] [1 (2 ¬16 9 or 5

B

x1 x2 y1 y2 5 (2) 4 (1) 40. B; , 2, 2 2 2

(3.5, 1.5)

D

E

Proof:

Page 226 Maintain Your Skills Q 3

1. isosceles triangle JKN with vertex N 2. N J N K

6. 2 3, 4 1 6. Congruence of is transitive. (Statements 3 and 5)

AC C B and A C C B , so ABC is a right isosceles triangle. 38. Sample answer: Placing the figures on the coordinate plane is useful in proofs. We can use coordinate geometry to prove theorems and verify properties. Answers should include the following. • flow proof, two-column proofs, paragraph proofs, informal proofs, and coordinate proofs • Sample answer: The Isosceles Triangle Theorem can be proved using coordinate proof.

41. Given: 3 4 Prove: Q R Q S

Reasons

4. J K L M 5. 1 3, 4 2 5. Corr. are .

2a 0 Slope of A C 0 (2a) or 1; 2a 0 B slope of C 0 2a or 1.

Statements

1

R

4

2

S

Reasons

1. 3 4

1. Given

3. If 2 form a linear pair, then they are suppl.

4. 2 1

4. Angles that are suppl. to are .

5. Q R Q S

5. Conv. of Isos. Th.

1. A D C E

1. Given

2. A E, D C

2. Alt. int. are .

D C E 3. A

3. Given

4. ABD EBC

4. ASA W

V X Z

2. Def. of linear pair 2. 2 and 4 form a linear pair. 1 and 3 form a linear pair. 3. 2 and 4 are supplementary. 1 and 3 are supplementary.

Reasons

44. Given: WX X Y , V Z Prove: W V Y Z

Proof: Statements

Statements

Y

Proof: Statements

Reasons

1. W X X Y , V Z

1. Given

2. WXV YXZ

2. Vert. are .

3. WXV YXZ

3. AAS

4. W V Y Z

4. CPCTC

45. BCA DAC, so B C A D ; if alternate interior are , lines are .

115

Chapter 4

46. h j; Sample answer: The angle in the figure whose measure is 111 is congruent to the angle on the other side of line h such that the angles are vertical angles. Then 111 69 180, so h j because consecutive interior angles are supplementary. 47. l m; 2 lines to the same line are parallel

2 (4 19. MN ¬(7 ) 3 2)2 ¬16 4 or 20 QR ¬[4 (2)]2 (7 3)2 ¬4 16 or 20 2 (6 NP ¬(6 ) 7 4)2 ¬1 4 or 5 RS ¬[6 (4)]2 (6 7)2 ¬4 1 or 5 2 (6 MP ¬(6 ) 3 2)2 ¬9 16 or 5 QS ¬[6 (2)]2 (6 3)2 ¬16 9 or 5 Each pair of corresponding sides has the same measure. Therefore, MNP QRS by SSS. 20. Given: DF bisects D CDE, C E D F . Prove: DGC DGE

Chapter 4 Study Guide and Review Page 227 1. h 4. j 7. b

Vocabulary and Concept Check 2. g 5. a 8. f

3. d 6. c

Pages 228–230 Lesson-by-Lesson Review 9. ABC has one angle with measure greater than 90, so it is an obtuse triangle. ABC has two congruent sides, so it is isosceles. 10. BDP has a right angle, so it is a right triangle. The measure of one of the acute angles is 60 so the measure of the other acute angle is 90 60 or 30. BDP cannot be isosceles or equilateral so it must be scalene. 11. BPQ has at least two congruent sides, and one of the base angles is 60° so the other base angle must also be 60°. Then the third angle is 180 (60 60) or 60 so BPQ is equiangular and hence equilateral. 12. m1 45 40 85 13. m2 m1 70 ¬180 m2 85 70 ¬180 m2 ¬25 14. m3 m1 ¬180 m3 85 ¬180 m3 ¬95 15.E D, F C, G B, E F D C , G F C B , G E B D 16. FGC DLC, GCF LCD, GFC LDC, G C L C , C F C D , F G D L 17. KNC RKE, NCK KER, CKN ERK, N C K E , C K E R , K N R K 18. MN ¬(4 0)2 ) (3 32 ¬16 0 or 4 2 (6 QR ¬(2 ) 5 6)2 ¬9 0 or 3 NP ¬[4 (4)]2 (6 3)2 ¬0 9 or 3 2 (2 RS ¬(2 ) 2 6)2 ¬0 16 or 4 MP ¬(4 0)2 ) (6 32 ¬16 9 or 5 2 (2 QS ¬(2 ) 5 6)2 ¬9 16 or 5 Each pair of corresponding sides does not have the same measure. Therefore, MNP is not congruent to QRS. MNP is congruent to SRQ.

Chapter 4

G

C

E

F

Proof: Statements

Reasons

1. DF bisects CDE, E C D F .

1. Given

G D G 2. D 3. CDF EDF


4. DGC is a rt. ; DGE is a rt. 5. DGC DGE

4. Def. of segments

6. DGC DGE

3. Def. of bisector

5. All rt. are . 6. ASA

21. Given: DGC DGE, GCF GEF Prove: DFC DFE

D

C

G

E

F Proof: Statements

Reasons

1. DGC DGE, GCF GEF

1. Given

2. CDG EDG, C D E D , and CFD EFD 3. DFC DFE

2. CPCTC 3. AAS

22. PQU is isosceles with base P U . The base angles of PQU are congruent, so P PUQ. We are given mP 32, so mPUQ 32.

116

23. PQU is isosceles with base P U . PRT is isosceles with base P T . Step 1 The base angles of PQU are congruent. Let x represent mP and mQUP. mP mQUP mPQU ¬180 x x 40 ¬180 2x ¬140 x ¬70 So, mP mQUP 70. Step 2 The base angles of PRT are congruent. By Step 1 we know mP 70, so mT 70. Let y represent mR. mP mT mR ¬180 70 70 y ¬180 y ¬40 So, mR 40. 24. RQS is isosceles with base Q S . The base angles of RQS are congruent, so RQS RSQ. We are given mRQS 75, so mRSQ 75. Let y represent mR. mRQS mRSQ mR ¬180 75 75 y ¬180 y ¬30 So, mR 30. 25. RQS is isosceles with base Q S . RPT is isosceles with base P T . Step 1 The base angles of RQS are congruent, and mRQS 80 so mRSQ 80. Let x represent mR. mRQS mRSQ mR ¬180 80 80 x ¬180 x ¬20 So, mR 20. Step 2 The base angles of RPT are congruent. Let y represent mP and mT. mP mT mR ¬180 y y 20 ¬180 2y ¬160 y ¬80 So, mP mT 80. 26. • Use the origin as vertex T of the triangle. • Place the base of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since I is on the x-axis, its y-coordinate is 0. Its x-coordinate is 4a because the base of the triangle is 4a units long. • Since TRI is isosceles, the x-coordinate of R is halfway between 0 and 4a, or 2a. We cannot determine the y-coordinate in terms of a, so call it b. y

T(0, 0)

27. • Use the origin as vertex B of the triangle. • Place side B D along the positive x-axis. • Position the triangle in the first quadrant. • Since D is on the x-axis, its y-coordinate is 0. Its x-coordinate is 6m because each side length is 6m units long. • Since BCD is equilateral, the x-coordinate of C is halfway between 0 and 6m, or 3m. We cannot determine the y-coordinate in terms of m, so call it n. y

C(3m, n)

D(6m, 0) x

B(0, 0)

28. • Use the origin as vertex K of the triangle, the right angle. • Place leg K L along the positive x-axis. • Place leg J K along the positive y-axis. • Since L is on the x-axis, its y-coordinate is 0. Its x-coordinate is a because one of the leg lengths is a units. • Since J is on the y-axis, its x-coordinate is 0. Its y-coordinate is b because the other leg length is b units. y

J(0, b)

K(0, 0)

L(a, 0)

x

Chapter 4 Practice Test Page 231 1. b 2. a 3. c 4. PCD is obtuse because PCD has measure greater than 90. 5. PAC is isosceles because P A P C . 6. PBA, PBC, and PBD are right triangles because P B A D , so PBA and PBD are right angles. 7. m1 100 ¬180 m1 ¬80 8. m2 75 ¬180 m2 ¬105 9. m3 m1 ¬m2 m3 80 ¬105 m3 ¬25 10. D P, E Q, F R, D E P Q , F E Q R , D F P R 11. F H, M N, G J, F M H N , G M N J , F G H J 12. X Z, Y Y, Z X, X YZ Y, Z Y YX , and X Z Z X

R(2a, b)

I(4a, 0) x

117

Chapter 4

17. Given: ABE, BCE AB 22, AC 44, AE 36, CD 36 A and C are right angles. Prove: ABE CBD

2 13. JK ¬[2 1)] ( [3)] (22 ¬9 1 or 10 MN ¬[2 (6)]2 [1)] (72 ¬16 4 6 or 80 2 [1)] KL ¬(3 ) 2 (32 ¬1 16 or 17 2 NP ¬[5 2)] ( (3 1)2 ¬49 4 or 53 2 JL ¬[3 1)] ( [1 (2)]2 ¬16 9 or 5 2 MP ¬[5 6)] ( [3 (7)]2 ¬121 100 or 221 Corresponding sides are not congruent, so JKL is not congruent to MNP. 14. Given: JKM JNM K Prove: JKL JNL

J

M

E

L

N JNM

Given

JK JN KJL NJL CPCTC

JKL SAS

JNL

JL

JL

Reflexive Prop.

H . The base angles 15. FJH is isosceles with base J are congruent, so mJ mFHJ. Let x represent mJ and mFHJ. mJ mFHJ mJFH ¬180 x x 34 ¬180 2x ¬146 x ¬73 So, mJ mFHJ 73. 16. JFH is isosceles with base J H . FGH is isosceles with base F H . Step 1 The base angles of FGH are congruent. Let x represent mGFH and mGHF. mGFH mGHF mG ¬180 x x 32 ¬180 2x ¬148 x ¬74 So, mGFH mGHF 74. Step 2 GHF FHJ GHJ by the Angle Addition Postulate. mGHF mFHJ ¬mGHJ 74 mFHJ ¬152 mFHJ¬78 Step 3 The base angles of JFH are congruent, so J FHJ. Then mJ mFHJ 78. Let y represent mJFH. mJ mFHJ mJFH ¬180 78 78 y ¬180 y ¬24 So, mJFH 24.

Chapter 4

B

C

D

Proof: We are given that AB 22 and AC 44. By the Segment Addition Postulate, AB BC ¬AC 22 BC ¬44 Substitution BC ¬22 Subtract 22 from each side. Since AB BC, then by the definition of congruent segments, A B B C . We are given that AE 36 and CD 36. Then also by the definition of congruent segments, E A C D . We are additionally given that both A and C are right angles. Since all right angles are congruent, A C. Since A B B C , A C, and A E C D , then by SAS, ABE CBD. 18. C; JGH is isosceles with base J H . Step 1 FGH is a right triangle, so the sum of the measures of the two acute angles is 90. mF mH ¬90 28 mH ¬90 mH ¬62 Step 2 The base angles of JGH are congruent, so H HJG. Then mHJG mH 62. Let x represent mJGH. mH mHJG mJGH ¬180 62 62 x ¬180 x ¬56 So, mJGH 56.

Proof: JKM

A

Chapter 4 Standardized Test Practice Pages 232–233 1. B; find when the populations will be equal. Let x represent the number of years after 2002. 2010 150x ¬1040 340x 2010 ¬1040 190x 970 ¬190x 5.1 ¬x The populations will be equal about 5 years after 2002, or 2007. Since the population of Shelbyville is growing at a faster rate than the population of Capitol City, the following year, 2008, the population of Shelbyville will be greater than the population of Capitol City. 2. C; grams measure mass, feet and meters measure length, and liters measure volumes of liquid.

118

3. B; let x represent the length of the shadow. Use the Pythagorean Theorem to solve for x to the nearest foot. 122 ¬92 x2 144 ¬81 x2 63 ¬x2 8 ¬x The shadow is about 8 feet long. 4. D 5. D; the slope of the line in Kris’s graph can be found using points (0, 3) and (4, 11).

12. The angle adjacent to the 105° angle has measure 180 105 or 75. The tower is an isosceles triangle, so its base angles are congruent. Let x represent the measure of the angle at the top of the tower. x 75 75 180 x 30 The measure of the angle at the top of the tower is 30. 13. BCA EFD since all right angles are congruent. A C D F since the planes are equidistant from the ground. CAB FDE since the planes descend at the same angle. So, ABC DEF by ASA. 14. Let x represent mA. A B B C so A C and mC mA x. Also, mB 3(mA) or 3x. x x 3x ¬180 5x ¬180 x ¬36 mC x 36 15a. The railroad ties that run across train tracks are parallel. So, x 90 because the angle whose measure is x is supplementary to an angle that corresponds to the angle whose measure is known to be 90. 15b. Perpendicular lines, because the ties are parallel and the tracks are parallel so all angles are 90° angles. 15c. They are congruent. Sample answers: Both are right angles; they are supplementary angles; they are corresponding angles. 16a. Sample answer: A

(y2 y1) 3 11 4 0 or 2 (x2 x1)

6.

7.

8. 9. 10. 11.

The slope of the line in Mitzi’s graph is the same as the slope of the line in Kris’s graph, or 2. So the line in Mitzi’s graph has equation y 2x b, or 2x y b. The only answer of this form is 2x y 1, so b 1 or b 1. B; mEFG ¬mFDE mFED 9x 7 ¬5x 5x 9x 7 ¬10x 7 ¬x mEFG 9(7) 7 70 C; ABD CBD, so CBD is a flip of ABD over the x-axis. Corresponding points have the same x-coordinate and opposite y-coordinates. A; if we know B C C E then ACB DCE by SAS. 3s2(2s3 7) 6s5 21s2 Brian’s second statement was the converse of his original statement. Explore: Creston (C) and Dixville (D) are endpoints of the base of an isosceles triangle formed by Creston, Dixville, and Milford. We are looking for the coordinates (x, 1) to satisfy these conditions.

5x

y

M(1, 3)

B

1)

(3x

13)

C

16b. From the Angle Sum Theorem, we know that mA mB mC 180. Substituting the given measures, 5x 4x 1 3x 13 180. Solve for x to find that x 14. Substitute 14 for x to find the measures: 5x 5(14) or 70, 4x 1 4(14) 1 or 55, and 3x 13 3(14) 13 or 55. 16c. If two angles of a triangle are congruent, then the sides opposite those angles are congruent (Converse of the Isosceles Triangle Theorem). Since two sides of this triangle are congruent, it is an isosceles triangle (Definition of Isosceles Triangle).

x

C(1, 1)

(4x

D(x, 1)

Solve: The x-coordinate of the vertex angle is halfway between the x-coordinates of C and D. (1 x) So, 1 ¬ 2 2 ¬1 x 3 ¬x Examine: C and D are the base vertices of the isosceles triangle formed by C, D, and M.

119

Chapter 4

Chapter 5 Relationships in Triangles 3.

Page 235 Getting Started

B

x1 x2 y1 y2 12 4 5 15 1. , ¬ 2, 2

2

x

x 2

2

y y 2

¬(4, 5)

22 10 25 10 1 2 1 2 2. , ¬ 2, 2

¬(6, 7.5)

x1 x2 y1 y2 19 (20) 7 (3) 3. , ¬ 2, 2

2

2

A

D 6. They intersect at the same point. 7. B N

S A

M

5-1

Bisectors, Medians, and Altitudes

Page 242 Check for Understanding 1. Sample answer: Both pass through the midpoint of a side. A perpendicular bisector is perpendicular to the side of a triangle, and does not necessarily pass through the vertex opposite the side, while a median does pass through the vertex and is not necessarily perpendicular to the side.

C Q

2. They intersect at the same point.

Chapter 5

C

8. They intersect at the same point. 9. See students’ work. 10. Acute: all intersect inside the triangle; obtuse: perpendicular bisectors and altitudes intersect outside the triangle; medians and angle bisectors intersect inside the triangle; right: perpendicular bisectors intersect on the hypotenuse, medians intersect inside the triangle, altitudes intersect on the vertex of the right angle, and angle bisectors intersect inside the triangle. 11. For an isosceles triangle, the perpendicular bisector and median of the side opposite the vertex are the same as the altitude from the vertex angle and the angle bisector of the vertex angle. In an equilateral triangle, the perpendicular bisector and median of each side is the same as the altitude to each side and the angle bisector of the angle opposite each side.

U M

L

A

T D

P

C

A

B N

C

B F E H

Pages 236–237 Geometry Activity: Bisectors, Medians, and Altitudes R

N

4. They intersect at the same point. 5.

¬(0.5, 5) 4. m1 104 ¬180 m1 ¬76 5. m2 36 ¬104 m2 ¬68 6. m3 104 ¬180 m3 ¬76 7. m4 40 8. m5 m4 ¬104 m5 40 ¬104 m5 ¬64 9. m5 m6 ¬90 64 m6 ¬90 m6 ¬26 10. m7 40 ¬180 m7 ¬140 11. m8 m6 ¬m4 m8 26 ¬40 m8 ¬14 12. Let p and q represent the parts of the statement. p: the three sides of one triangle are congruent to the three sides of a second triangle q: the triangles are congruent Statement (1): p → q Statement (2): q No conclusion can be reached because the truth of p is unknown. 13. Let p and q represent the parts of the statement. p: a polygon is a triangle q: the sum of the measures of the angles is 180 Statement (1): p → q Statement (2): p Since the given statements are true, use the Law of Detachment to conclude that the sum of the measures of the angles of polygon JKL is 180.

1.

M

O

120

5. Given: XY X Z M Y and Z N are medians. Prove: Y M Z N X

2. Sample answer:

M

Z Y Proof: Statements

3. Sample answer: An altitude and angle bisector of a triangle are the same segment in an equilateral triangle. 4. Find an equation of the perpendicular bisector of A B .

A (3, 3)

N

1. XY X Z , Y M and Z N are medians.

y

B (3, 2)

x

Z . 2. M is the midpoint of X N is the midpoint of X Y . 3. XY XZ

2. Def. of median

4. X M M Z , X N N Y

4. Midpoint Theorem

5. XM MZ, XN NY

5. Def. of

6. XM MZ XZ, XN NY XY


7. XM MZ XN NY

7. Substitution

8. MZ MZ NY NY

8. Substitution

C (1, 4) 1

B is 6, so the slope of the The slope of A perpendicular bisector is 6. The midpoint of A B

is 0, 5 2 .

9. 2MZ 2NY

y y1 ¬m(x x1)

10. MZ NY

y 5 2 ¬6(x 0) y 5 2 ¬6x y ¬6x 5 2

Reasons 1. Given

3. Def. of

9. Addition Property 10. Division Property

11. M Z N Y

11. Def. of

12. XZY XYZ

Find an equation of the perpendicular bisector of C B . The slope of B C is 3, so the slope of the perpendicular bisector of B C is 1 3 . The midpoint of B C is (2, 1). y y1 ¬m(x x1)

13. Y Z Y Z 14. MYZ NZY

12. Isosceles Triangle Theorem 13. Reflexive Property 14. SAS

y (1) ¬1 3 (x 2)

15. Y M Z N

15. CPCTC

2 y 1 ¬1 3x 3 1 1 y ¬3x 3

6. Find x. TQ ¬TR 2x ¬8 x ¬4 Find y. PT ¬TR 3y 1 ¬8 3y ¬9 y ¬3 Find z. Line bisects P R , so z 4 7, or z 3.

Solve a system of equations to find the point of intersection of the perpendicular bisectors. Find x. y ¬6x 5 2 1 5 1 3x 3 ¬6x 2

2x 2 ¬36x 15 17 ¬38x 17 ¬x 38


17 Replace x with 38 in one of the equations to find the y-coordinate.

7. Find an equation of the median from D(4, 0) to the midpoint of E F . The midpoint of E F is (1, 5). The slope of the median is 1. y y1 ¬m(x x1) y 0 ¬1(x 4) y ¬x 4

17 5 y ¬6 38 2 7 y ¬ 38 The coordinates of the circumcenter of ABC 17 7 are 38 , 38 .

121

Chapter 5

Find x. y ¬x 4 y ¬3 2x 6

y

E (2, 4)

F (0, 6)

D (4, 0)

3 x 6 ¬x 4 2 6 ¬5 2x 4 5 2 ¬2 x 4 5 ¬x Replace x with 4 5 in one of the equations to find

x

the y-coordinate.

Find an equation of the median from F(0, 6) to the midpoint of D E . The midpoint of D E is (1, 2). The slope of the median is 4. y y1 ¬m(x x1) y 6 ¬4(x 0) y 6 ¬4x y ¬4x 6 Solve a system of equations to find the point of intersection of the medians. Find x. y ¬x 4 y ¬4x 6 4x 6 ¬x 4 6 ¬3x 4 2 ¬3x 2 ¬x 3 Replace x with 2 3 in one of the equations to find the y-coordinate. y 2 3 4

y ¬4 5 4 y ¬4 4 5

4 The coordinates of the orthocenter are 4 5 , 4 5 .

9.

E . The slope of D E is 2 of D 3 , so the slope of the 3 E perpendicular bisector is 2. The midpoint of D is (1, 2). y y1 ¬m(x x1) y 2 ¬3 2 (x 1)

y

3 y 2 ¬3 2x 2

F (0, 6)

D (4, 0)

x

Find an equation of the perpendicular bisector

1 The coordinates of the centroid are 2 3 , 3 3 .

E (2, 4)

F (0, 6)

D (4, 0)

y 3 1 3

8.

y

E (2, 4)

3

y ¬2 x 1 2

Find an equation of the perpendicular bisector of F E . The slope of E F is 1, so the slope of the perpendicular bisector is 1. The midpoint of E F is (1, 5). y y1 ¬m(x x1) y 5 ¬1[x (1)] y 5 ¬x 1 y ¬x 4 Solve a system of equations to find the point of intersection of the perpendicular bisectors. Find x. y ¬x 4

x

Find an equation of the altitude from D(4, 0) to F E . The slope of E F is 1, so the slope of the altitude is 1. y y1 ¬m(x x1) y 0 ¬1(x 4) y ¬x 4 Find an equation of the altitude from F(0, 6) to E D . The slope of D E is 2 3 , so the slope of the

1 y ¬3 2x 2 1 x 4 ¬3 2x 2 7 ¬5x 2 2

altitude is 3 2. y y1 ¬m(x x1) y 6 ¬3 2 (x 0)

7 ¬5x 7 ¬x 5

y 6 ¬3 2x

Replace x with 7 5 in one of the equations to find the y-coordinate.

y ¬3 2x 6 Solve a system of equations to find the point of intersection of the altitudes.

y ¬7 5 4 1 3 y ¬ 5

The coordinates of the circumcenter are 75, 153 or 1 25, 2 35. Chapter 5

122

10. Given: CD is the perpendicular bisector of A B . E is a point on C D . Prove: EB EA C B E

GL is a median of EGH. 12. Given: M J is a median of IJK. EGH IJK Prove: G L J M I E

D A Proof: D C is the perpendicular bisector of A B . By definition of perpendicular bisector, D is the midpoint of A B . Thus, A D B D by the Midpoint Theorem. CDA and CDB are right angles by definition of perpendicular. Since all right angles are congruent, CDA CDB. Since E is a point on C D , EDA and EDB are right angles and are congruent. By the Reflexive Property, D E E D . Thus, EDA EDB by SAS. B E E A because CPCTC, and by definition of congruence, EB EA. 11. Given: UVW is isosceles with vertex angle UVW. V Y is the bisector of UVW. Prove: Y V is a median. U Y

L H

M K G

J

Proof: Statements 1. GL is a median of EGH, M J is a median of IJK, and EGH IJK.

1. Given

2. GH J K , GHL JKM, E H IK

2. CPCTC

3. EH IK

3. Def. of

4. E L L H , IM M K

4. Def. of median

5. EL LH, IM MK

5. Def. of

6. EL LH EH, IM MK IK


7. EL LH IM MK

7. Substitution

8. LH LH MK MK

8. Substitution

9. 2LH 2MK

9. Addition Property

V

W Proof: Statements Reasons 1. Given 1. UVW is an isosceles triangle with vertex angle UVW, Y V is the bisector of UVW. 2. Def. of isosceles V W V 2. U 3. Def. of angle 3. UVY WVY bisector 4. Reflexive 4. Y V Y V Property 5. SAS 5. UVY WVY 6. U Y W Y

6. CPCTC

W . 7. Y is the midpoint of U

7. Def. of midpoint

8. Y V is a median.

8. Def. of median

Reasons

10. LH MK


11. L H M K

11. Def of

12. GHL JKM

12. SAS

13. G L J M

13. CPCTC

MS is an altitude of MNQ, so MSQ is a right 13. angle. m1 m2 ¬90 3x 11 7x 9 ¬90 10x 20 ¬90 10x ¬70 x ¬7 m2 ¬7(7) 9 ¬58 14. M S is a median of MNQ, so Q S S N . 3a 14 ¬2a 1 a 14 ¬1 a ¬15 mMSQ ¬7a 1 ¬7(15) 1 ¬106 S M is not an altitude of MNQ because mMSQ 106.

123

Chapter 5

15. W P is an angle bisector, so mHWP 1mHWA. 2

23. PX is an altitude of PQR, so PXR is a right angle. mPXR ¬90 2a 10 ¬90 2a ¬80 a ¬40 24. R Z bisects PRQ, so mPRZ mZRQ. 4b 17 ¬3b 4 b 17 ¬4 b ¬13 mPRZ ¬4(13) 17 ¬35 25. Q Y is a median, so PY YR. 2c 1 ¬4c 11 1 ¬2c 11 10 ¬2c 5 ¬c PR ¬PY YR ¬2(5) 1 4(5) 11 ¬10 1 20 11 ¬18 26. QY is perpendicular to P R , so QYR is a right angle. mQYR ¬90 7b 6 ¬90 7b ¬84 b ¬12 27. X is the midpoint of S T .

x 12 ¬1 2 (4x 16)

16.

17.

18. 19.

20. 21.

22.

x 12 ¬2x 8 12 ¬x 8 20 ¬x W P is a median, so A P P H . 3y 11 ¬7y 5 11 ¬4y 5 16 ¬4y 4 ¬y mPAW ¬3x 2 ¬3(20) 2 ¬58 mPWA mHWP because W P is an angle bisector. So, mPWA ¬x 12 ¬20 12 or 32 mWPA mPAW mPWA ¬180 mWPA 58 32 ¬180 mWPA ¬90 WPA is a right angle, so W P is also an altitude. P W bisects A H , so A P P H . 6r 4 ¬22 3r 3r 4 ¬22 3r ¬18 r ¬6 P W is perpendicular to A H , so mHPW 90. mWHA mHWP mHPW ¬180 8q 17 10 q 90 ¬180 9q 117 ¬180 9q ¬63 q ¬7 mHWP ¬10 q ¬10 7 ¬17 Always; each median is always completely contained in the interior of the triangle, so the intersection point must also be inside the triangle. sometimes; true for a right triangle but false for an equilateral triangle Never; an angle bisector lies between two sides of the triangle and is contained in the triangle up to the point where it intersects the opposite side. so, the intersection point of the three angle bisectors must also be inside the triangle. sometimes; true for an obtuse triangle but false for an acute triangle S P is a median of PQR, so Q S S R . 10x 7 ¬5x 3 5x 7 ¬3 5x ¬10 x ¬2 D A is an altitude of ABC, so ADC is a right angle. mADC ¬90 4x 6 ¬90 4x ¬96 x ¬24

Chapter 5

y

T (1, 8) S (1, 6)

R (3, 3) x

x x

y y

8 1 1 1 2 1 2 , ¬ , 6 2 2 2 2

¬(0, 7)

28. d

(x x1)2 (y2 y1)2 2 y

T (1, 8) S (1, 6)

R (3, 3) x

RX ¬ (0 3 )2 (7 3)2 ¬ 9 16 or 5 units

124

(y y ) (x2 x1) 7 3 4 0 3 or 3 y

2 1 29. m

13. mCEA mCEA 180

T (1, 8) S (1, 6)

R (3, 3) x

30. No, R X is not an altitude of RST. The slope of S T is 1. The product of the slopes of S T and R X , not 1. Thus, the segments are not is 4 3 perpendicular.

14. 2(mCEA) 180

14. Substitution

15. mCEA 90


16. CEA and CEB are rt. .

16. Def. of rt.

17. C D A B

17. Def. of

18. CD is the perpendicular bisector of A B .

18. Def. of bisector

19. C and D are on the perpendicular bisector of A B .

19. Def. of points on a line

32. Given: BAC, P is in the interior of BAC, PD PE Prove: AP is the angle bisector of BAC D A B P

y

T (1, 8) S (1, 6)

E C Proof: Statements Reasons 1. BAC, P is in the interior 1. Given of BAC, PD PE 2. Def. of D P E 2. P

R (3, 3) x

31. Given: CA C B , A D B D Prove: C and D are on the perpendicular bisector of A B .

3. P D A B , P E AC

C

A

E

13. Substitution

4. ADP and AEP are rt. 5. ADP and AEP are rt. s

B

D Proof: Statements

Reasons

1. C A C B , A D B D

1. Given

D C D 2. C 3. ACD BCD


4. ACD BCD

4. CPCTC

5. C E C E


6. CEA CEB

6. SAS 7. CPCTC

7. A E B E 8. E is the midpoint of A B . 9. CEA CEB 10. CEA and CEB form a linear pair. 11. CEA and CEB are supplementary. 12. mCEA mCEB 180

3. Distance from a point to a line is measured along segment from the point to the line. 4. Def. of 5. Def. of rt.

6. A P A P


7. ADP AEP 8. DAP EAP is the angle bisector 9. AP of BAC

7. HL 8. CPCTC 9. Def. of bisector

8. Def. of midpoint 9. CPCTC 10. Def. of linear pair 11. Supplement Theorem 12. Def. of suppl.

125

Chapter 5

, 33. Given: ABC with angle bisectors AD BE, and , K CF P A B , K Q B C , K R A C Prove: KP KQ KR A R P E K F D

B

Page 245 Maintain Your Skills 43. Sample answer: • Use the origin as vertex A of the triangle. • Place side AB along the positive x-axis. • Position the triangle in the first quadrant. • Since B is on the x-axis, its y-coordinate is 0. Its x-coordinate is n because A B is n units long. • Since ABC is equilateral, the x-coordinate of C is halfway between 0 and n, or n 2 . We cannot determine the y-coordinate in terms of n, so call it m.

C

Q

Proof: Statements Reasons 1. ABC with angle bisectors 1. Given , , K AD BE, and CF P A B , Q K B C , K R A C 2. Any point on 2. KP KQ, KQ KR, the bisector is KP KR equidistant from the sides of the angle. 3. Transitive 3. KP KQ KR Property

y

B(n, 0) x

A(0, 0)

44. Sample answer: • Use the origin as vertex D of the triangle. • Place the base of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since F is on the x-axis, its y-coordinate is 0. Its x-coordinate is a because the base of the triangle is a units long. • Since DEF is isosceles, the x-coordinate of E is halfway between 0 and a, or a 2 . We cannot determine the y-coordinate in terms of a, so call it b.

34. The flag is located at the intersection of the angle bisector between Amesbury and Stearns Roads and the perpendicular bisector of the segment joining Grand Tower and the park entrance. 16 2 (6) 35. 4 3 8 4 12 36. 8 3

y

37. C (–6, 12) y 12

E(5, 10)

C (n–2, m)

E(a–2, b)

A(16, 8)

8 D(–2, 8) 4 –4

O

F (9, 6)

4

8

12

45. Sample answer: • Use the origin as vertex H of the triangle. • Place leg H I along the positive y-axis. •G I is the hypotenuse so H is a right angle and leg G H is on the x-axis. Position G H on the positive x-axis. • Since G is on the x-axis, its y-coordinate is 0. Its x-coordinate is x because G H is x units long. • Since I is on the y-axis, its x-coordinate is 0. Its y-coordinate is 3x because HI 3GH or 3x.

16 x

38. The centroid has the same coordinates as the means of the vertices’ coordinates. 39. The altitude will be the same for both triangles, and the bases will be congruent, so the areas will be equal. 40. Sample answer: You can balance a triangle on a pencil point by locating the center of gravity of the triangle. Answers should include the following. •centroid •

y

I (0, 3x)

H(0, 0) 41. C; GJ JH, so J is the midpoint of GH and J F is a median of FGH. 42. D; 3x ¬0.3y 10.0x ¬y y 10.0 ¬x

Chapter 5

F(a, 0) x

D(0, 0)

B(2, 4)

G(x, 0) x

46. MT M R by the converse of the Isosceles Triangle Theorem. 47. 5 11 by the Isosceles Triangle Theorem. 48. 7 10 by the Isosceles Triangle Theorem. 49. M L M N by the converse of the Isosceles Triangle Theorem. 50. It is everywhere equidistant.

126

6 5 3 51. 3 6. 8 16 because 8 1 5 5 52. 2.7 3 because 3 1.6 .

2.

19 19 53. 4.25 4 because 4 4.75. 1 8 1 9 1 8 54. 25 27 because 25 0.72 and 19 0 3 . 27 0.7

3.

4.

Page 246 Reading Mathematics: Math Words and Everyday Words 1. Sample answer: A median of a triangle is a segment that has one endpoint at a vertex and the other at the midpoint of the opposite side; the everyday meaning says it is a paved or planted strip in the middle of a highway. 2. Sample answer: the intersection of two or more lines or curves, the top of the head, the highest point 3. Sample answer: in a trapezoid, the segment joining the midpoints of the legs; the middle value of a set of data that has been arranged into an ordered sequence 4. Sample answer: a separate piece of something; a portion cut off from a geometric figure by one or more points, lines, or planes.

5-2

5.

Inequalities and Triangles

Page 249 Geometry Activity: Inequalities for Sides and Angles of Triangles 1. 2. 3. 4.

Sample answer: It is the greatest measure. Sample answer: It is the least measure. See students’ work. Sample answer: The measures of the angles opposite the sides are in the same order as the lengths of the respective sides. 6.

Page 251


1. never; L

K

J

J is a right angle. Since mJ = 2 mK, 90 ¬2 mK 45 ¬mK mL 180 90 45 45 mL mK, so LKJ is isosceles, and KJ LJ. Let KJ LJ 1. If the statement in the problem is true, then LK 2. Since LKJ is a right triangle, the Pythagorean Theorem applies. 12 12 ¬22 2 ¬4 This is a false statement, so the statement in the problem is never true.

7.

8.

127

A C B Sample answer: mCAB, mACB, mABC; B C , B A , A C Grace; she placed the shorter side with the smaller angle and the longer side with the larger angle. Explore: Compare the measure of 2 to the measures of 1 and 4 Plan: Use properties and theorems of real numbers to compare the angle measures. Solve: Compare m1 to m2. By the Exterior Angle Theorem, m2 m1 m4. Since angle measures are positive numbers and from the definition of inequality, m2 m1. Compare m4 to m2. Again, by the Exterior Angle Theorem, m2 m1 m4. The definition of inequality states that if m2 m1 m4 then m2 m4. Examine: m2 is greater than m1 and m4. Therefore, 2 has the greatest measure. Explore: Compare the measure of 3 to the measures of 2 and 5. Plan: Use properties and theorems of real numbers to compare the angle measures. Solve: Compare m2 to m3. By the Exterior Angle Theorem, m3 m2 m5. Since angle measures are positive numbers and from the definition of inequality, m3 m2. Compare m5 to m3. Again, by the Exterior Angle Theorem, m3 m2 m5. The definition of inequality states that if m3 m2 m5 then m3 m5. Examine: m3 is greater than m2 and m5. Therefore, 3 has the greatest measure. Explore: Compare the measure of 3 to the measures of 1, 2, 4, and 5. Plan: Use properties and theorems of real numbers to compare the angle measures. Solve: From Exercise 4, m2 m1 and m2 m4. From Exercise 5, m3 m2 and m3 m5. Then by transitivity, m3 m1 and m3 m4. Examine: m3 is greater than m1, m2, m4, and m5. Therefore, 3 has the greatest measure. By the Exterior Angle Inequality Theorem, m1 m4 and m1 m5 m6 so m1 m5 and m6. Thus, the measures of 4, 5, and 6 are all less than m1. By the Exterior Angle Inequality Theorem, m1 m5 m6 and m7 m5 m6 so m1 m6 and m7 m6. Thus, the measures of 1 and 7 are greater than m6.

Chapter 5

19. Explore: Compare the measure of 7 to the measures of 3 and 5. Plan: Use properties and theorems of real numbers to compare angle measures. Solve: Compare m7 to m3. By the Exterior Angle Inequality Theorem, m7 m3. Compare m7 to m5. By the Exterior Angle Inequality Theorem, m7 m5. Examine: m7 is greater than m3 and m5. Therefore, 7 has the greatest measure. 20. Explore: Compare the measure of 1 to the measures of 2 and 6. Plan: Use properties and theorems of real numbers to compare angle measures. Solve: Compare m1 to m2. By the Exterior Angle Inequality Theorem, m1 m2. Compare m1 to m6. By the Exterior Angle Inequality Theorem, m1 m6. Examine: m1 is greater than m2 and m6. Therefore, 1 has the greatest measure. 21. Explore: Compare the measure of 7 to the measures of 5 and 8. Plan: Use properties and theorems of real numbers to compare angle measures. Solve: Compare m7 to m5. By the Exterior Angle Inequality Theorem, m7 m5. Compare m7 to m8. By the Exterior Angle Inequality Theorem, m7 m8. Examine: m7 is greater than m5 and m8. Therefore, 7 has the greatest measure. 22. Explore: Compare the measure of 2 to the measures of 6 and 8. Plan: Use properties and theorems of real numbers to compare angle measures. Solve: Compare m2 to m6. By the Exterior Angle Inequality Theorem, m2 m6. Compare m2 to m8. Let x be the measure of the third angle of the triangle whose other angles are 3 and 4. Then, by the Exterior Angle Inequality Theorem, m2 (x m8). Since angle measures are positive numbers and from the definition of inequality, m2 m8. Examine: m2 is greater than m6 and m8. Therefore, 2 has the greatest measure. 23. By the Exterior Angle Inequality Theorem, m5 m7, m5 m10, and m5 m2 m8 so m5 m2 and m5 m8. Thus, the measures of 2, 7, 8, and 10 are all less than m5. 24. By the Exterior Angle Inequality Theorem, m4 m6, m1 m6 m9 so m1 m6 and m11 m6 m9 so m11 m6. Thus, the measures of 1, 4, and 11 are all greater than m6.

9. By the Exterior Angle Inequality Theorem, m7 m2 m3 and m7 m5 m6, so m7 m2, m7 m3, m7 m5, and m7 m6. Thus, the measures of 2, 3, 5, and 6 are less than m7. 10. The side opposite WXY is longer than the side opposite XYW, so mWXY mXYW. 11. The side opposite XZY is shorter than the side opposite XYZ, so mXZY mXYZ. 12. The side opposite WYX is shorter than the side opposite XWY, so mWYX mXWY. 13. A E is opposite a 30° angle, and E B is opposite a 110° angle. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so AE EB. 14. C E is opposite CDE, and mCDE 180 (50 55) or 75. C D is opposite a 55° angle. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so CE CD. 15. B C is opposite BEC, and mBEC 180 (40 100) or 40. E C is opposite a 40° angle. Thus, BC EC. 16. Second base; the angle opposite the side from third base to second base is smaller than the angle opposite the side from third to first. Therefore, the distance from third to second is shorter than the distance from third to first.

Pages 252–253 Practice and Apply 17. Explore: Compare the measure of 1 to the measures of 2 and 4. Plan: Use properties and theorems of real numbers to compare angle measures. Solve: Compare m1 to m2. By the Exterior Angle Inequality Theorem, m1 m2. Compare m1 to m4. By the Exterior Angle Inequality Theorem, m1 m4. Examine: m1 is greater than m2 and m4. Therefore, 1 has the greatest measure. 18. Explore: Compare the measure of 2 to the measures of 4 and 6. Plan: Use properties and theorems of real numbers to compare angle measures. Solve: Compare m2 to m4. By the Exterior Angle Inequality Theorem, m2 m4. Compare m2 to m6. By the Exterior Angle Inequality Theorem, m2 m6. Examine: m2 is greater than m4 and m6. Therefore, 2 has the greatest measure.

Chapter 5

128

36. Given: PR P Q ; QR QP Prove: mP mQ

25. By the Exterior Angle Inequality Theorem, m3 m10 and m5 m10. Thus, the measures of 3 and 5 are greater than m10. 26. By the Exterior Angle Inequality Theorem, m1 m3, m1 m6, and m1 m9. Thus, the measures of 3, 6, and 9 are all less than m1. 27. By the Exterior Angle Inequality Theorem, m8 m9, m7 m9, m3 m9, and m1 m9. Thus, the measures of 8, 7, 3, and 1 are all greater than m9. 28. By the Exterior Angle Inequality Theorem, m8 m2, m8 m4, m8 m5, and m8 m9. Thus, the measures of 2, 4, 5, and 9 are all less than m8. 29. The side opposite KAJ is shorter than the side opposite AJK, so mKAJ mAJK. 30. The side opposite MJY is longer than the side opposite JYM, so mMJY mJYM. 31. The side opposite SMJ is longer than the side opposite MJS, so mSMJ mMJS. 32. The side opposite AKJ is longer than the side opposite JAK, so mAKJ mJAK. 33. The side opposite MYJ is shorter than the side opposite JMY, so mMYJ mJMY. 34. The side opposite JSY is longer than the side opposite JYS, so mJSY mJYS. 35. Given: JM J L L J K L Prove: m1 m2 L

R

Q Proof:

1

J

M

Proof: Statements

Reasons

1. J M J L , J L K L 2. LKJ LJK

1. Given

3. mLKJ mLJK

3. Def. of

4. m1 mLKJ

4. Ext. Inequality Theorem

5. m1 mLJK

5. Substitution

6. mLJK m2

6. Ext. Inequality Theorem

7. m1 m2

7. Trans. Prop. of Inequality

Statements 1. QR QP

Reasons 1. Given

2. mP mR

2. If one side of a is longer than another, then the opp. the longer side is greater than the opposite the shorter side.

R P Q 3. P

3. Given

4. Q R

4. Isosceles Theorem

5. mQ mR

5. Def. of

6. mP mQ

6. Substitution

37. ZY is opposite a 45° angle. Y R is opposite YZR, and mYZR 180 (95 45) or 40. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so ZY YR. 38. S R is opposite a 43° angle. Z S is opposite ZRS, and mZRS 180 (43 97) or 40. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so SR ZS. 39. R Z is opposite a 97° angle. S R is opposite a 43° angle. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so RZ SR. 40. Z Y is opposite a 45° angle. R Z is opposite a 95° angle. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so ZY RZ. 41. T Y is opposite TZY. mTZY mZYT 91, so mTZY 91 66 or 25. Z Y is opposite an 89° angle. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so TY ZY. 42. T Y is opposite TZY. mTZY mZYT 91, so mTZY 91 66 or 25. Z T is opposite a 66° angle. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle, so TY ZT.

2

K

P

2. Isosceles Theorem

129

Chapter 5

mP mQ mR ¬180 9n 4 4n 16 68 2n ¬180 11n 48 ¬180 11n ¬132 n ¬12 mP ¬9(12) 4 or 104 mQ ¬4(12) 16 or 32 mR ¬68 2(12) or 44 mQ mR mP, so the sides of PQR in order from shortest to longest are P R , P Q , Q R . 49. mP mQ mR ¬180 3n 20 2n 37 4n 15 ¬180 9n 72 ¬180 9n ¬108 n ¬12 mP ¬3(12) 20 or 56 mQ ¬2(12) 37 or 61 mR ¬4(12) 15 or 63 mP mQ mR, so the sides of PQR in order from shortest to longest are Q R , P R , PQ . 50. mP mQ mR ¬180 4n 61 67 3n n 74 ¬180 2n 202 ¬180 2n ¬22 n ¬11 mP ¬4(11) 61 or 17 mQ ¬67 3(11) or 100 mR ¬11 74 or 63 mP mR mQ, so the sides of PQR in order from shortest to longest are Q R , P Q , P R .

43. KL ¬ (1 3)2 (5 2)2 ¬ 16 9 or 5 2 LM ¬ [3 (1)] ( 7 5)2 ¬ 4 14 4 ¬ 148 ¬12.2 KM ¬ (3 3)2 (7 2)2 ¬ 36 8 1 ¬ 117 ¬10.8 The side lengths in order from least to greatest are KL, KM, LM, so the angles in order from the least to the greatest measure are M, L, K. 44. Sample answer: Draw a triangle that satisfies the given information. Then draw the medians and measure them to find their lengths.

48.

C N

A

M O

B

In ABC, AB AC BC. Measure A M , B N, and C O . In this triangle CO BN AM. 45. 8x 4 11x 37 5x 21 ¬180 24x 12 ¬180 24x ¬192 x ¬8 8x 4 ¬8(8) 4 or 68 11x 37 ¬11(8) 37 or 51 5x 21 ¬5(8) 21 or 61 68 61 51, so the lengths of the legs of the trip in order from greatest to least are Phoenix to Atlanta, Des Moines to Phoenix, Atlanta to Des Moines. 46. mP mQ mR ¬180 9n 29 93 5n 10n 2 ¬180 14n 124 ¬180 14n ¬56 n ¬4 mP ¬9(4) 29 or 65 mQ ¬93 5(4) or 73 mR ¬10(4) 2 or 42 mR mP mQ, so the sides of PQR in order from shortest to longest are P Q , Q R , P R . 47. mP mQ mR ¬180 12n 9 62 3n 16n 2 ¬180 25n 55 ¬180 25n ¬125 n ¬5 mP ¬12(5) 9 or 51 mQ ¬62 3(5) or 47 mR ¬16(5) 2 or 82 mQ mP mR, so the sides of PQR in order from shortest to longest are P R , Q R , P Q .

Chapter 5

51. The angle opposite the side with length 3x inches has measure 180 163 or 17. The angle opposite the side with length 2(y 1) inches has measure x 180 (17 75) or 88. Thus, 2(y 1) 3. x 2(y 1) ¬3 x

y 1 ¬6 x

y ¬6 1

6 x y ¬¬ 6

52.

A

C T M Given: ABC is scalene; A M is the median from A to B C ; A T is the altitude from A to B C . Prove: AM AT ATB and ATM are right angles by the definition of altitude and mATB mATM because all right angles are congruent. By the Exterior Angle Inequality Theorem, mATB mAMT. So, mATM mAMT by Substitution. If one angle of a triangle has a greater measure than another angle, then the side opposite the greater angle is longer than the side opposite the lesser angle. Thus, AM AT. B

130

53.

mA mB mC ¬180 2y 12 y 18 4y 12 ¬180 7y 6 ¬180 7y ¬174 y ¬25 mA ¬2(25) 12 or 62 mB ¬25 18 or 7 mC ¬4(25) 12 or 112 mC mA so 3x 15 ¬4x 7 15 ¬x 7 8 ¬x CB 0, so 4x 7 ¬0 4x ¬7

9 71 12 101 2 2

2

90 ¬ 4

1 8 ¬ 9 4 4

90 2

12 71 3 101 2 2 2

DF ¬

2

90 ¬ 4

1 8 ¬ 9 4 4

7

x ¬4

90 2

7 Thus, 4 x 8.

BF DF, so B F D F and F is the midpoint of D B . Therefore, E F is a perpendicular bisector of D B .

54. Sample answer: The largest corner is opposite the longest side. Answers should include the following. • the Exterior Angle Inequality Theorem • the angle opposite the side that is 51 feet long 55. A; n p 180 m so m n 180 p

ab

0 b 60. x ¬ a 3 3 0 0 c y ¬3c 3

a b c D has coordinates D 3 , 3.

x 56. D; 1 2 x 3 ¬2 5 1

61. Label the midpoints of A B , B C , and C A as E, F, and G respectively. Then the coordinates of

5x 30 ¬4(x 1) 5x 30 ¬4x 4 x 30 ¬4 x ¬26

ab b E, F, and G are a 2, 0, 2, 2, and 2, 2 c respectively. The slope of A F a b , and the slope c


c

c of A D F . The slope of a b , so D is on A

57. D is on C B with C D D B and the slope of C D equals the slope of D B . DB ¬ (12 9)2 (3 1 2)2 ¬ 9 81 ¬ 90

c c G B D b 2a and the slope of B b 2a , 2c 2b a

so D is on B G . The slope of C E and the 2 c slope of C D E . Since D is 2b a , so D is on C

3 12 slope of D B ¬ 12 9

F , B G , and C E , it is the intersection point of on A the three segments.

9

¬3 or 3

62. T X, U Y, V Z, T U X Y , V U Y Z , T V X Z 63. C R, D S, G W, C D R S , G D S W , C G R W 64. B D, C G, F H, B C D G , F C G H , B F D H 65. slope of line containing (4, 8) and (2, 1): 8 1 9 9 2 4 2 2

D is 9 units down and 3 units to the right from B. The point C that is 9 units down and 3 units to the right from D has coordinates (12 3, 3 9) or (15, 6). Check that CD DB. CD ¬ (15 12)2 (6 3)2 ¬ 9 81 ¬ 90 C has coordinates (15, 6). 58. slope of B C 3 3 8 5 slope of AD 12 3 or 9

slope of line containing (x, 2) and (4, 5): 52 3 4 x 4 x

No, A D is not an altitude of ABC because 5 9 (3) 1. 90 59. slope of B D 3 71 2 6 slope of E F ¬ 101 2 6

2

BF ¬

Solve for x. Since the lines are perpendicular, 3 2 4 x ¬9

2

3(9) ¬2(4 x) 27 ¬8 2x 19 ¬2x 9.5 ¬x 66. true; 2ab ¬2(2)(5) ¬20 67. false; c(b a) ¬6(5 2) ¬6(3) ¬18

11

2 ¬ 41 2

¬1 3 B D EF because 1 3 (3) 1.

131

Chapter 5

68. true; a c ¬2 6 or 8 a b ¬2 5 or 7 a c ¬a b since 8 7

3. Sample answer: ABC is scalene. Given: ABC; AB BC; BC AC; AB AC Prove: ABC is scalene. A

Page 254 Practice Quiz 1 1.

2.

3.

4.

5. 6. 7.

8. 9.

10.

BD ¬DC 4x 9 ¬7x 6 9 ¬3x 6 15 ¬3x 5 ¬x D A B C , so mADC 90. 2y 6 ¬90 2y ¬96 y ¬48 Never; a median is a segment from one vertex to the side opposite the vertex and never intersects any other vertex. Always; an angle bisector lies between two sides of the triangle and is contained in the triangle up to the point where it intersects the opposite side. So, the intersection point of the three angle bisectors must also be inside the triangle. sometimes; true for an obtuse triangle but false for an acute triangle sometimes; true for right triangles but false for other triangles No triangle; by Exercise 4, the angle bisectors always intersect at a point in the interior of the triangle. mT mS mU, so the sides of STU in order from longest to shortest are S U , T U , S T . mQ mR mS ¬180 3x 20 2x 37 4x 15 ¬180 9x 72 ¬180 9x ¬108 x ¬12 mQ ¬3(12) 20 or 56 mR ¬2(12) 37 or 61 mS ¬4(12) 15 or 63 mQ mR mS, so the sides of QRS in order from shortest to longest are R S , Q S , Q R .

5-3

4. 5. 6. 7.

8.

9.

Indirect Proof


C A Proof: Step 1 Assume that there can be more than one obtuse angle in ABC. Step 2 An obtuse angle has a measure greater than 90. Suppose A and B are obtuse angles. Then mA mB 180 and mA mB mC 180. Step 3 The conclusion contradicts the fact that the sum of the measures of the angles of a triangle equals 180. Thus, there can be at most one obtuse angle in ABC.

1. If a statement is shown to be false, then its opposite must be true. 2. Sample answer: Indirect proofs are proved using the contrapositive, showing Q → P. In a direct proof, it would be shown that P → Q. For example, indirect reasoning can be used to prove that a person is not guilty of a crime by assuming the person is guilty, then contradicting evidence to show that the person could not have committed the crime.

Chapter 5

C B Proof: Step 1 Assume ABC is not scalene. Case 1: ABC is isoceles. If ABC is isosceles, then AB BC, BC AC, or AB AC. This contradicts the given information, so ABC is not isosceles. Case 2: ABC is equilateral. In order for a triangle to be equilateral, it must also be isosceles, and Case 1 proved that ABC is not isosceles. Thus, ABC is not equilateral. Therefore, ABC is scalene. x 5 The lines are not parallel. The lines are not parallel. Given: a 0 1 Prove: a 0 Proof: 1 Step 1 Assume a

0. 1 1 Step 2 a

0; a a

0 a, 1 0 Step 3 The conclusion that 1 0 is false, so the 1 assumption that a

0 must be false. 1 Therefore, a 0. Given: n is odd. Prove: n2 is odd. Proof: Step 1 Assume n2 is even. Step 2 n is odd, so n can be expressed as 2a 1. n2 ¬(2a 1)2 Substitution ¬(2a 1)(2a 1) Multiply. ¬4a2 4a 1 Simplify. ¬2(2a2 2a) 1 Distributive Property Step 3 2(2a2 2a) 1 is an odd number. This contradicts the assumption, so the assumption must be false. Thus n2 is odd. Given: ABC Prove: There can be no more than one obtuse angle in ABC. B

132

10. Given: m n Prove: Lines m and n intersect at exactly one point.

16. A median of an isosceles triangle is not an altitude. 17. Points P, Q, and R are noncollinear.

m n

18. The angle bisector of the vertex angle of an isosceles triangle is not an altitude of the triangle.

Proof: Case 1: m and n intersect at more than one point. Step 1 Assume that m and n intersect at more than one point. Step 2 Lines m and n intersect at points P and Q. Both lines m and n contain P and Q. Step 3 By postulate, there is exactly one line through any two points. Thus the assumption is false, and lines m and n intersect in no more than one point. Case 2: m and n do not intersect. Step 1 Assume that m and n do not intersect. Step 2 If lines m and n do not intersect, then they are parallel. Step 3 This conclusion contradicts the given information. Therefore the assumption is false, and lines m and n intersect in at least one point. Combining the two cases, lines m and n intersect in no more than one point and no less than one point. So lines m and n intersect in exactly one point. 11. Given: ABC is a right triangle; C is a right angle. Prove: AB BC and AB AC A

1 19. Given: a 0 Prove: a is negative. Proof: Step 1 Assume a 0. a 0 since that would 1 make a undefined.

Step 2

1 a¬ 0 1 a a ¬ (0)a

1¬ 0 Step 3 1 0, so the assumption must be false. Thus, a must be negative. 20. Given: n2 is even. Prove: n2 is divisible by 4. Proof: Step 1 Assume n2 is not divisible by 4. In other words, 4 is not a factor of n2. Step 2 If the square of a numbers is even, then the number is also even. So, if n2 is even, then n must be even. Let n ¬2a. n ¬2a n2 ¬(2a)2 or 4a2 Step 3 4 is a factor of n2, which contradicts the assumption. 21. Given: PQ P R 1 2 Prove: PZ is not a median of PQR. P

C

B

12

Proof: Step 1 Assume that the hypotenuse of a right triangle is not the longest side. That is, AB BC or AB AC. Step 2 If AB BC, then mC mA. Since mC 90, mA 90. So, mC mA 180. By the same reasoning, if AB AC, then mC mB 180. Step 3 Both relationships contradict the fact that the sum of the measures of the angles of a triangle equals 180. Therefore, the hypotenuse must be the longest side of a right triangle. 12. Given: x y 270 Prove: x 135 or y 135 Proof: Step 1 Assume x 135 and y 135. Step 2 x y 270 Step 3 This contradicts the fact that x y 270. Therefore, at least one of the stages was longer than 135 miles.

Q Z R Proof: Step 1 Assume P Z is a median of PQR. Step 2 If P Z is a median of PQR, then Z is the midpoint of Q R , and Q Z R Z . P Z P Z by the Reflexive Property. PZQ PZR by SSS. 1 2 by CPCTC. Step 3 This conclusion contradicts the given fact 1 2. Thus, P Z is not a median of PQR. 22. Given: m2 m1 Prove: m

t

2

1 3

m

Proof: Step 1 Assume that m. Step 2 If m, then 1 2 because they are corresponding angles. Thus, m1 m2. Step 3 This contradicts the given fact that m1 m2. Thus the assumption m is false. Therefore, m.

Pages 258–260 Practice and Apply 13. PQ S T 14. x 4 15. 6 cannot be expressed as a b.

133

Chapter 5

23. Given: a 0, b 0, and a b a Prove: 1 b Proof: Step 1 Assume that a b 1. Step 2 Case 1 Case 2 a¬¬1 b

a¬ 1 b

a¬¬b a¬ b Step 3 The conclusion of both cases contradicts the given fact a b. a Thus, 1. b

A 24. Given: AB C Prove: 1 2 A

2 C 1 B Proof: Step 1 Assume that 1 2. Step 2 If 1 2, then the sides opposite the angles are congruent. Thus A B A C . Step 3 The conclusion contradicts the given information. Thus 1 2 is false. Therefore, 1 2. 25. Given: ABC and ABD are equilateral. ACD is not equilateral. Prove: BCD is not equilateral. C A

27.

B D Proof: Step 1 Assume that BCD is an equilateral triangle. Step 2 If BCD is an equilateral triangle, then C B C D D B . Since ABC and ABD are equilateral triangles, A C A B B C and A D A B D B . By the Transitive Property, A C A D C D . Therefore, ACD is an equilateral triangle. Step 3 This conclusion contradicts the given information. Thus, the assumption is false. Therefore, BCD is not an equilateral triangle. 26. Given: mA mABC Prove: BC AC D A

28.

29.

30. B C Proof: Assume BC AC. By the Comparison Property, BC AC or BC AC. Case 1: If BC AC, then ABC A by the Isosceles Triangle Theorem (If two sides of a triangle are congruent, then the angles opposite those sides are congruent.) But, ABC A contradicts the given statement that mA mABC. So, BC AC. Chapter 5

31.

32.

134

Case 2: If BC AC, then there must be a point D between A and C so that D C B C . Draw the auxiliary segment B D . Since DC BC, by the Isosceles Triangle Theorem BDC DBC. Now BDC is an exterior angle of BAD, and by the Exterior Angles Inequality Theorem (the measure of an exterior angle of a triangle is greater than the measure of either corresponding remote interior angle) mBDC mA. By the Angle Addition Postulate, mABC mABD mDBC. Then by the definition of inequality, mABC mDBC. By Substitution and the Transitive Property of Inequality, mABC mA. But this contradicts the given statement that mA mABC. In both cases, a contradiction was found, and hence our assumption must have been false. Therefore, BC AC. Use r dt, t 3, and d 175. Proof: Step 1 Assume that Ramon’s average speed was greater than or equal to 60 miles per hour, r 60. Step 2 Case 1 Case 2 r ¬60 r ¬60 17 5 17 5 ? 60 ¬ 3 ¬60 3 60 ¬58.3 58.3 ¬60 Step 3 The conclusions are false, so the assumption must be false. Therefore, Ramon’s average speed was less than 60 miles per hour. A majority is greater than half or 50%. Proof: Step 1 Assume that the percent of college-bound seniors receiving information from guidance counselors is less than 50%. Step 2 By examining the graph, you can see that 56% of college-bound seniors received information from guidance counselors. Step 3 Since 56% 50%, the assumption is false. Therefore, a majority of college-bound seniors received information from guidance counselors. 1500 15% ¬225 1500 0.15 ¬225 225 ¬225 teachers and friends; 15% 18% 33%, 33% 31% Yes; if you assume the client was at the scene of the crime, it is contradicted by his presence in Chicago at that time. Thus, the assumption that he was present at the crime is false. See students’ work.

40. Given: QT is a median. QRS is isosceles with base R S . Prove: Q T bisects SQR Q

33. Proof: Step 1 Assume that 2 is a rational number. Step 2 If 2 is a rational number, it can be written as a b , where a and b are integers with no common factors, and b 0. If 2 2 2 2 a 2 a b , then 2 b2 , and 2b a . Thus a is an even number, as is a.Because a is even it can be written as 2n. 2b2 ¬a2 2b2 ¬(2n)2 2b2 ¬4n2 b2 ¬2n2 b2 is an even number. So, b is also an even number. Step 3 Because b and a are both even numbers, they have a common factor of 2. This contradicts the definition of rational 2 is not rational. numbers. Therefore, 34. Sample answer: Indirect proof is sometimes used in mystery novels. Answers should include the following. • Sherlock Holmes would disprove all possibilities except the actual solution to a mystery. • medical diagnosis, trials, scientific research 35. D; x 80 ¬140 x ¬60 A, B, and C are true. D is not true.

S

Statements

Reasons

1. Q T is a median. QRS is 1. Given isosceles with base R S . T S T 2. R

2. Def. of median

3. Q R Q S 4. Q T Q T

3. Def. of isosceles 4. Reflexive Prop.

5. QRT QST

5. SSS

6. SQT RQT

6. CPCTC

T bisects SQR 7. Q

7. Def. of bisector

G is an angle bisector of 41. Given: ABC DEF; B ABC. E H is an angle bisector of DEF. Prove: B G E H G C


A D

H F Proof: Statements

37. The angle in MOP with the greatest measure is opposite the side with the greatest measure. Side M O has measure 9, which is greater than all other sides of the triangle. So, P has the greatest measure. 38. The angle in LMN with the least measure is M opposite the side with the least measure. Side L has measure 6, which is less than all other sides of the triangle. So, N has the least measure. 39. Given: C D is an angle bisector. C D is an altitude. Prove: ABC is isosceles. C

D

R

Proof:

8 7 6 1 36. A; 15 14 10 16

B

T

A

Proof:

B E Reasons

1. ABC DEF

1. Given

2. A D, A B D E , ABC DEF

2. CPCTC

3. BG is an angle bisector of ABC. E H is an angle bisector of DEF.

3. Given

4. ABG GBC, DEH HEF

4. Def. of bisector

5. mABC mDEF

5. Def. of

6. mABG mGBC, mDEH mHEF

6. Def. of

7. mABC mABG mGBC, mDEF mDEH mHEF

7. Angle Addition Property 8. Substitution

Statements

Reasons

1. C D is an angle bisector. D C is an altitude. 2. ACD BCD

1. Given

D A B 3. C

3. Def. of altitude

8. mABC mABG mABG, mDEF mDEH mDEH

4. CDA and CDB are rt.

4. lines form 4 rt. .

9. mABG mABG mDEH mDEH

9. Substitution

5. CDA CDB

5. All rt. are .

10. 2mABG 2mDEH

10. Substitution

D C D 6. C

6. Reflexive Prop.

11. mABG mDEH

11. Division

7. ACD BCD

7. ASA

12. ABG mDEH

12. Def. of

8. A C B C

8. CPCTC

13. ABG DEH

13. ASA

9. Def. of isosceles

14. B G E H

14. CPCTC

9. ABC is isosceles.

2. Def. of bisector

135

Chapter 5

42. mR mS mA ¬180 41 109 mA ¬180 150 mA ¬180 mA ¬30 43. y y1 ¬m(x x1) y 3 ¬2(x 4) 44. y y1 ¬m(x x1) y (2) ¬3(x 2) y 2 ¬3(x 2) 45. y y1 ¬m(x x1) y (9) ¬11[x (4)] y 9 ¬11(x 4) ? 46. true; 19 10¬ 11 9¬ 11 ? 47. false; 31 17¬ 12 14¬ 12 ? 48. true; 38 76¬ 109 114¬ 109

5-4

8. Let the measure of the third side be n. 7 12¬ n 7 n¬ 12 12 n¬ 7 n¬ 5 n¬ 5 19¬ n or n 19 Graph the inequalities on the same number line. 5

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9 11 13 15 17 19

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5

Find the intersection. The range of values that fit all three inequalities is 5 n 19. 9. Let the measure of the third side be n. 14 23¬ n 14 n¬ 23 23 n¬ 14 37¬ n or n 37 n¬ 9 n¬ 9 Graph the inequalities on the same number line. 9

6

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12 15 18 21 24 27 30 33 36 3739

n¬ 37 9

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9 12 15 18 21 24 27 30 33 36 3739

n¬ 9 9

n¬ 9 9

3

6

Find the intersection. The range of values that fit all three inequalities is 9 n 37. 10. Let the measure of the third side be n. 22 34¬ n 22 n¬ 34 34 n¬ 22 56¬ n or n 56 n¬ 12 n¬ 12 Graph the inequalities on the same number line.

2 2 3

4. Check each inequality. ? ? ? 5 4¬ 3 4 3¬ 5 5 3¬ 4 9¬ 3 ✓ 7¬ 5 ✓ 8¬ 4 ✓ All of the inequalities are true, so 5, 4, and 3 can be the lengths of the sides of a triangle.

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54 56

n¬ 56

?

5. 5 10¬ 15 15¬ 15 Because the sum of two measures equals the third measure, the sides cannot form a triangle.

12

n¬ 12

?

6. 30.1 0.8¬ 31 30.9¬ 31 Because the sum of two measures is less than the third measure, the sides cannot form a triangle. 7. Check each inequality.

12

n¬ 12 12

6

Find the intersection. The range of values that fit all three inequalities is 12 n 56. 11. Let the measure of the third side be n. 15 18¬ n 15 n¬ 18 18 n¬ 15 33¬ n or n 33 n¬ 3 n¬ 3

?

5.6 5.2¬ 10.1 5.6 10.1¬ 5.2 15.7¬ 5.2 ✓ 10.8¬ 10.1 ✓ ? 5.2 10.1¬ 5.6 15.3¬ 5.6 ✓ All of the inequalities are true, so 5.6, 10.1, and 5.2 can be the lengths of the sides of a triangle.

Chapter 5

1

5

1. Sample answer: If the lines are not horizontal, then the segment connecting their y-intercepts is not perpendicular to either line. Since distance is measured along a perpendicular segment, this segment cannot be used. 2. Jameson; 5 10 13 but 5 8 13. 3. Sample answer: 2, 3, 4 and 1, 2, 3

?

0

n¬ 5


1

1

n¬ 5

The Triangle Inequality

4

3

n¬ 19

136

Graph the inequalities on the same number line. 3

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18. Check each inequality. ? ? ? 18 32¬ 21 18 21¬ 32 32 21¬ 18 50¬ 21 ✓ 39¬ 32 ✓ 53¬ 18 ✓ All of the inequalities are true, so 18, 32, and 21 can be the lengths of the sides of a triangle. 19. Check each inequality. ? ? ? 9 21¬ 20 9 20¬ 21 20 21¬ 9 30¬ 20 ✓ 29¬ 21 ✓ 41¬ 9 ✓ All of the inequalities are true, so 9, 21, and 20 can be the lengths of the sides of a triangle.

n 33 3

n3 3

n 3 3

?

20. 5 9¬ 17 14¬ 17 Because the sum of two measures is less than the third measure, the sides cannot form a triangle. 21. Check each inequality. ? ? 17 30¬ 30 30 30¬ 17 47¬ 30 ✓ 60¬ 17 ✓ All of the inequalities are true, so 17, 30, and 30 can be the lengths of the sides of a triangle. 22. Check each inequality. ? ? ? 8.4 7.2¬ 3.5 8.4 3.5¬ 7.2 3.5 7.2¬ 8.4 15.6¬ 3.5 ✓ 11.9¬ 7.2 ✓ 10.7¬ 8.4 ✓ All of the inequalities are true, so 8.4, 7.2, and 3.5 can be the lengths of the sides of a triangle. 23. Check each inequality. ? ? ? 4 0.9¬ 4.1 4 4.1¬ 0.9 4.1 0.9¬ 4 4.9¬ 4.1 ✓ 8.1¬ 0.9 ✓ 5¬ 4 ✓ All of the inequalities are true, so 4, 0.9, and 4.1 can be the lengths of the sides of a triangle.

Find the intersection. The range of values that fit all three inequalities is 3 n 33. 12. Given: P Q plane M Prove: PQ is the shortest segment from P to plane M. P

M

Q

Proof: By definition, P Q is perpendicular to plane M if it is perpendicular to every line in M that intersects it. But since the perpendicular segment from a point to a line is the shortest segment from the point to the line, that perpendicular segment is the shortest segment from the point to each of these lines. Therefore, Q P is the shortest segment from P to M. 13. B; Let x be the length of each of the congruent sides of the triangle. x x¬ 10 x 10¬ x 2x¬ 10 10¬ 0 true for all x x¬ 5 The side length x is a whole number greater than 5. The smallest number x for which this is true is 6. Thus, the answer is choice B.

?

24. 2.2 12¬ 14.3 14.2¬ 14.3 Because the sum of two measures is less than the third measure, the sides cannot form a triangle. ?

25. 0.18 0.21¬ 0.52 0.39¬ 0.52 Because the sum of two measures is less than the third measure, the sides cannot form a triangle. 26. Let the measure of the third side be n. 5 11¬ n 5 n¬ 11 11 n¬ 5 16¬ n or n 16 n¬ 6 n¬ 6 Graph the inequalities on the same number line.

Pages 264–265 Practice and Apply ?


6

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15. 2 6¬ 11 8¬ 11 Because the sum of two measures is less than the third measure, the sides cannot form a triangle. 16. Check each inequality. ? ? 8 8¬ 15 8 15¬ 8 16¬ 15 ✓ 23¬ 8 ✓ All of the inequalities are true, so 8, 8, and 15 can be the lengths of the sides of a triangle.

6

n6 6

n 6 6

Find the intersection. The range of values that fit all three inequalities is 6 n 16.

?


137

Chapter 5

27. Let the measure of the third side be n. 7 9¬ n 7 n¬ 9 9 n¬ 7 16¬ n or n 16 n¬ 2 n¬ 2 Graph the inequalities on the same number line.

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Find the intersection. The range of values that fit all three inequalities is 29 n 93. 32. Let the measure of the third side be n. 30 30¬ n 30 n¬ 30 60¬ n or n 60 n¬ 0 Graph the inequalities on the same number line.

n¬ 5 20

n¬ 5 20

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n¬ 68

Chapter 5

20

n¬ 24

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138

34. Let the measure of the third side be n. 57 55¬ n 57 n¬ 55 55 n¬ 57 112¬ n or n 112 n¬ 2 n¬ 2 Graph the inequalities on the same number line. 10

0

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Graph the inequalities on the same number line. 100

100 110 112 120

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A D Proof: Statements 1. B ACB

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140

2. A B A C

2. If two are , the sides opposite the two are .

0

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100 120 140 150 160 180 200

3. AB AC

3. Def. of segments

n¬ 150 160

180 200

Reasons 1. Given

n¬ 0


60

45

30

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0

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30

45

60

4. AD AC CD 4. Triangle Inequality 5. AD AB CD 5. Substitution HE E G 39. Given: Prove: HE FG EF H

75 83 90

G

n¬ 83 75 73 60

45

30

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60

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60 73 75

90

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n¬ 73 75

E

F

Proof: Statements

90

n¬ 73 75

120

Find the intersection. The range of values that fit all three inequalities is 97 n 101. 38. Given: B ACB Prove: AD AB CD

Find the intersection. The range of values that fit all three inequalities is 2 n 112. 35. Let the measure of the third side be n. 75 75¬ n 75 n¬ 75 150¬ n or n 150 n¬ 0 Graph the inequalities on the same number line.

20

100

n¬ 97

n¬ 2

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40

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n¬ 112

10

80

n¬ 101

1. H E E G

Reasons 1. Given

2. HE EG

2. Def. of segments

3. EG FG EF

3. Triangle Inequality

4. HE FG EF

4. Substitution

Find the intersection. The range of values that fit all three inequalities is 73 n 83. 37. Let the measure of the third side be n. 99 2¬ n 99 n¬ 2 2 n¬ 99 101¬ n or n 101 n¬ 97 n¬ 97

139

Chapter 5

40. Given: ABC Prove: AC BC AB A

D Proof:

C

42. LM ¬[22 (2 4)]2 [20 (19 )]2 ¬ 4 15 21 ¬ 1525 ¬39.1 2 ( MN ¬ [5 (22)] 7 20) 2 ¬ 289 729 ¬ 1018 ¬31.9 LN ¬ [5 (24 )]2 [ 7 (19) ]2 ¬ 361 144 ¬ 505 ¬22.5 ? ? LM MN¬ LN LM LN¬ MN ? ? 39.1 31.9¬ 22.5 39.1 22.5¬ 31.9 71¬ 22.5 ✓ 61.6¬ 31.9 ✓ ? LN MN¬ LM ? 22.5 31.9¬ 39.1 54.4¬ 39.1 ✓ All of the inequalities are true, so the coordinates can be the vertices of a triangle. 43. XY ¬ (16 0)2 [12 (8 )]2 ¬ 256 16 ¬ 272 ¬16.49 YZ ¬ (28 16)2 [15 (12)] 2 ¬ 144 9 ¬ 153 ¬12.37 XZ ¬ (28 0)2 [15 (8 )]2 ¬ 784 49 ¬ 833 ¬28.86 ? XY YZ¬ XZ ? 16.49 12.37¬ 28.86 28.86¬ 28.86 Because the sum of two measures equals the third measure, the sides cannot form a triangle and so the coordinates cannot be the vertices of a triangle. 44. RS ¬ (3 1)2 [20 (4)] 2 ¬ 16 2 56 ¬ 272 ¬16.5 RT ¬ (5 1 )2 [1 2 (4)] 2 ¬ 16 2 56 ¬ 272 ¬16.5 2 ST ¬ [5 (3)] [12 (2 0)]2 ¬ 64 1 024 ¬ 1088 ¬33

B

Statements

Reasons

1. Construct C D so that C is between B and D and C D AC .

1. Ruler Postulate

2. CD AC

2. Definition of

3. CAD ADC

3. Isosceles Triangle Theorem 4. Definition of angles

4. mCAD mADC 5. mBAC mCAD mBAD

5. Angle Addition Postulate

6. mBAC mADC mBAD

6. Substitution

7. mADC mBAD

7. Definition of inequality

8. AB BD

8. If an angle of a triangle is greater than a second angle, then the side opposite the greater angle is longer than the side opposite the lesser angle.

9. BD BC CD 10. AB BC CD 11. AB BC AC

9. Segment Addition Postulate 10. Substitution 11. Substitution (Steps 2, 10)

(2 5 )2 ( 4 8)2 41. AB ¬ ¬ 9 14 4 ¬ 153 ¬12.4 BC ¬ (3 2 )2 [1 (4)]2 ¬ 25 9 ¬ 34 ¬5.8 AC ¬ (3 5 )2 (1 8)2 ¬ 64 8 1 ¬ 145 ¬12.0 ? ? AB BC¬ AC AB AC¬ BC ? ? 12.4 5.8¬ 12.0 12.4 12.0¬ 5.8 18.2¬ 12.0 ✓ 24.4¬ 5.8 ✓ ? AC BC¬ AB ? 12.0 5.8¬ 12.4 17.8¬ 12.4 ✓ All of the inequalities are true, so the coordinates can be the vertices of a triangle. Chapter 5

140

?

RS RT¬ ST

8; 2, 3, 7; 2, 4, 6; and 2, 5, 5. Check each of these triples using the Triangle Inequality. 219 228 237 246 2 5 5 and 5 5 2, so there could be a triangle with side lengths 2, 5, and 5 units. Determine whether any triangle can have a side with 3 segments. If one side has length 3, then the possible triples of side lengths are 3, 1, 8; 3, 2, 7; 3, 3, 6; and 3, 4, 5. Check each of these triples using the Triangle Inequality. 318 327 336 3 4 5 and 3 5 4 and 4 5 3, so there could be a triangle with side lengths 3, 4, and 5 units. Determine whether any triangle can have a side with 4 segments. If one side has length 4, then the possible triples of side lengths are 4, 1, 7; 4, 2, 6; 4, 3, 5; and 4, 4, 4. Check each of these triples using the Triangle Inequality. Note that we have already shown that there can be a triangle with sides 4, 3, and 5 units. 417 426 4 4 4, so there could be a triangle with side lengths 4, 4, and 4 units. By examining all of the triples we have considered to this point, we can see that all possible triples have been listed and checked. Therefore, there are 3 triangles that can be formed using the rope shown in the figure. 48. 14¬ m 17, so m is either 15 or 16 feet. 13¬ n 17, so n is 14, 15, or 16 feet. Check all possible triples using the triangle inequality. ? ? ? 2 15¬ 14 2 14¬ 15 14 15¬ 2 17¬ 14 ✓ 16¬ 15 ✓ 29¬ 2 ✓ ? ? 2 15¬ 15 15 15¬ 2 17¬ 15 ✓ 30¬ 2 ✓ ? ? ? 2 15¬ 16 2 16¬ 15 15 16¬ 2 17¬ 16 ✓ 18¬ 15 ✓ 31¬ 2 ✓ ? 2 16¬ 14 2 14¬ 16 18¬ 14 ✓ 16¬ 16 ? ? ? 2 16¬ 15 2 15¬ 16 15 16¬ 2 18¬ 15 ✓ 17¬ 16 ✓ 31¬ 2 ✓ ? ? 2 16¬ 16 16 16¬ 2 18¬ 16 ✓ 32¬ 2 ✓ The possible triangles that can be made from sides with measures 2 ft, m ft, and n ft are (2 ft, 15 ft, 14 ft), (2 ft, 15 ft, 15 ft), (2 ft, 15 ft, 16 ft), and (2 ft, 16 ft, 16 ft). 49. Of the 4 possible triangles listed in Exercise 48, 2 2 1 are isosceles, so the probability is 4 or 2.

?

16.5 16.5¬ 33 33¬ 33 Because the sum of two measures equals the third measure, the sides cannot form a triangle and so the coordinates cannot be the vertices of a triangle. 45. Consider all possible triples using the lengths 3, 4, 5, 6, and 12. ? ? ? 3 4¬ 5 4 5¬ 3 3 5¬ 4 7¬ 5 ✓ 9¬ 3 ✓ 8¬ 4 ✓ ? ? ? 3 4¬ 6 4 6¬ 3 3 6¬ 4 7¬ 6 ✓ 10¬ 3 ✓ 9¬ 4 ✓ 3 4¬ 12 7¬ 12 ? ? ? 4 5¬ 6 4 6¬ 5 5 6¬ 4 9¬ 6 ✓ 10¬ 5 ✓ 11¬ 4 ✓ ? 4 5¬ 12 9¬ 12 ? ? ? 3 5¬ 6 5 6¬ 3 3 6¬ 5 8¬ 6 ✓ 11¬ 3 ✓ 9¬ 5 ✓ ? 3 5¬ 12 8¬ 12 ? 3 6¬ 12 9¬ 12 ? 4 6¬ 12 10¬ 12 ? 5 6¬ 12 11¬ 12 Of all possible triples, 4 of them satisfy the triangle inequality, so there are 4 possible triangles. 46. 3 4 5 12, which is divisible by 3 3 4 6 13, which is not divisible by 3 4 5 6 15, which is divisible by 3 3 5 6 14, which is not divisible by 3 Carlota could make 2 different triangles with a perimeter that is divisible by 3. 47. The rope has 13 knots that determine 12 segments of the rope. We need to determine how many triangles there are whose perimeter is 12. First determine whether any triangle can have a side with 1 segment. If one side has length 1, then the possible triples of side lengths are 1, 1, 10; 1, 2, 9; 1, 3, 8; 1, 4, 7; and 1, 5, 6. Check each of these triples using the Triangle Inequality. 1 1 10 129 138 147 156 Therefore, there is no possible triangle with one side of length 1 and perimeter 12. Determine whether any triangle can have a side with 2 segments. If one side has length 2, then the possible triples of side lengths are 2, 1, 9; 2, 2,

141

Chapter 5

50. Sample answer: The length of any side of a triangle is greater than the differences between the lengths of the other two sides. Paragraph Proof: By the Triangle Inequality Theorem, for ABC with side measures a, b, and c, a b c, b c a, and c a b. Using the Subtraction Property of Inequality, a c b, b a c, and c b a. 51. Sample answer: You can use the Triangle Inequality Theorem to verify the shortest route between two locations. Answers should include the following. • A longer route might be better if you want to collect frequent flier miles. • A straight route might not always be available. 52. D; If the perimeter is 29, the measure of the third side is 10. ? ? ? 7 10¬ 12 7 12¬ 10 10 12¬ 7 17¬ 12 ✓ 19¬ 10 ✓ 22¬ 7 ✓ So, 7, 12, and 10 could be the sides of a triangle with perimeter 29. If the perimeter is 34, the measure of the third side is 15. ? ? ? 7 15¬ 12 7 12¬ 15 12 15¬ 7 22¬ 12 ✓ 19¬ 15 ✓ 27¬ 7 ✓ So, 7, 12, and 15 could be the sides of a triangle with perimeter 34. If the perimeter is 37, the measure of the third side is 18. ? ? ? 7 18¬ 12 7 12¬ 18 12 18¬ 7 25¬ 12 ✓ 19¬ 18 ✓ 30¬ 7 ✓ So, 7, 12, and 18 could be the sides of a triangle with perimeter 37. If the perimeter is 38, the measure of the third side is 19. ? 7 12¬ 19 19¬ 19 So, 7, 12, and 19 cannot be the sides of a triangle. 53. A; If the graphs of the equations do intersect, then we can solve the system of equations and find the coordinates of any points of intersection. Substitute x for y in the equation (x 5)2 ( y 5)2 4 and solve for x. (x 5)2 [(x) 5]2¬ 4 2 x 10x 25 x2 10x 25¬ 4 2x2 50¬ 4 2x2¬ 46 x2¬ 23 Because there is no real number x whose square is equal to 23, there are no points of intersection.

Chapter 5

Page 266 Maintain Your Skills 54. Given: P is a point not on line . Prove: PQ is the only line through P perpendicular to . 1 Q

P 2

R

Proof: Statements

Reasons

is not the only line 1. Assumption 1. PQ through P perpendicular to . 2. 1 and 2 are right 2. lines form 4 rt. . angles. 3. m1 90, m2 90 3. Def. of rt. 4. m1 m2 mQPR 180

4. The sum of in a is 180.

5. 90 90 mQPR 180 6. mQPR 0

5. Substitution 6. Subtraction Property

This contradicts the fact that the measure of an is the only line angle is greater than 0. Thus, PQ through P perpendicular to . 55. mP mQ mR¬ 180 7x 8 8x 10 7x 6¬ 180 22x 4¬ 180 22x¬ 176 x¬ 8 mP¬ 7(8) 8 or 64 mQ¬ 8(8) 10 or 54 mR¬ 7(8) 6 or 62 mP mR mQ, so the sides of PQR in order from longest to shortest are Q R , P Q , P R . 56. mP mQ mR¬ 180 3x 44 68 3x x 61¬ 180 x 173¬ 180 x¬ 7 mP 3(7) 44 or 65 mQ 68 3(7) or 47 mR 7 61 or 68 mR mP mQ, so the sides of PQR in Q , Q R , P R . order from longest to shortest are P 2 (0 57. JK ¬ (0 0) 5)2 ¬ 0 25 or¬5 PQ ¬ (4 4 )2 (3 8)2 ¬ 0 25¬or¬5 KL ¬ (2 0)2 (0 0 )2 ¬ 4 0¬or¬2 2 (3 QR ¬ (6 4) 3)2 ¬ 4 0¬or¬2 JL ¬ (2 0)2 (0 5 )2 ¬ 4 25¬or 29 2 (3 PR ¬ (6 4) 8)2 ¬ 4 25¬or 29 The corresponding sides have the same measure and are congruent. JKL PQR by SSS.

142

2 ( 58. JK ¬ (1 6) 6 4)2 ¬ 25 1 00 or 125 PQ (5 0 )2 ( 3 7)2 ¬ 25 1 00 or 125 KL ¬ (9 1)2 [5 ( 6)]2 ¬ 100 121 or 221 QR ¬ (15 5)2 [8 (3)] 2 ¬ 100 121 or 221 JL ¬ (9 6)2 (5 4)2 ¬ 225 1 or 226 PR ¬ (15 0)2 (8 7 )2 ¬ 225 1 or 226 The corresponding sides have the same measure and are congruent. JKL PQR by SSS. 59. JK ¬ [1 ( 6)]2 [5 (3)]2 ¬ 49 6 4 or 113 2 [ PQ ¬ (5 2) 4 ( 11)]2 ¬ 9 49 or 58 2 ( KL ¬ (2 1) 2 5)2 ¬ 1 49 or 50 QR ¬ (10 5)2 [10 (4)] 2 ¬ 25 3 6 or 61 JL ¬ [2 ( 6)]2 [2 (3 )]2 ¬ 64 1 or 65 PR ¬ (10 2)2 [10 (1 1)]2 ¬ 64 1 or 65 The corresponding sides are not congruent, so the triangles are not congruent. 60. 3x 54¬ 90 3x¬ 36 x¬ 12 61. 8x 14¬ 3x 19 5x 14¬ 19 5x¬ 33 x¬ 6.6 62. 4x 7¬ 180 4x¬ 173 x¬ 43.25

4. Given: MO ¬ O N P M ¬ N P Prove: MOP NOP O M P N Proof: Step 1 Assume that MOP NOP. Step 2 We know that M O O N , and O P O P by the Reflexive Property. If MOP NOP, then MOP NOP by SAS. Then, M P P N by CPCTC. Step 3 The conclusion that M P N P contradicts the given information. Thus, the assumption is false. Therefore, MOP NOP. 5. Given: mADC mADB Prove: A D is not an altitude of ABC. A

C

D

B

Proof:

6.


1. The number 117 is not divisible by 13. 2. mC mD 3. Step 1 Assume that x 8. Step 2 7x¬ 56 x¬ 8 Step 3 The solution of 7x 56 contradicts the assumption. Thus, x 8 must be false. Therefore, x 8.

8.

9.

143

Statements

Reasons

1. AD is an altitude of ABC. 2. ADC and ADB are right angles.

1. Assumption

3. ADC ADB

3. All rt are .

4. mADC mADB

4. Def. of angles

2. Def. of altitude

This contradicts the given information that mADC mADB. Thus, A D is not an altitude of ABC. Check each inequality. ? ? ? 7 24¬ 25 7 25¬ 24 24 25¬ 7 31¬ 25 ✓ 32¬ 24 ✓ 49¬ 7 ✓ All of the inequalities are true, so 7, 24, and 25 can be the lengths of the sides of a triangle. ? 25 35¬ 60 60¬ 60 Because the sum of two measures equals the third measure, the sides cannot form a triangle. Check each inequality. ? ? ? 3 18¬ 20 18 20¬ 3 3 20¬ 18 21¬ 20 ✓ 38¬ 3 ✓ 23¬ 18 ✓ All of the inequalities are true, so 20, 3, and 18 can be the lengths of the sides of a triangle. Check each inequality. ? ? ? 5 10¬ 6 5 6¬ 10 6 10¬ 5 15¬ 6 ✓ 11¬ 10 ✓ 16¬ 5 ✓ All of the inequalities are true, so 5, 10, and 6 can be the lengths of the sides of a triangle.

Chapter 5

10. Let the measure of the third side be n. 57 32¬ n 57 n¬ 32 32 n¬ 57 89¬ n or n 89 n¬ 25 n¬ 25 Graph the inequalities on the same number line. 30

20

10

0

10

20

30

40

50

60

70

80

90

10

0

10

20

30

40

50

60

70

80

90

20

10

0

10

20 25 30

40

50

60

70

80

90

20

10

0

10

20 25 30

40

50

60

70

80 89 90

Also, the measure of any angle is always greater than 0. 7x 4¬ 0 7x¬ 4 x¬ 4 7 The two inequalities can be written as the 13 6 compound inequality 4 7 x 7 . 7. Given: P Q S Q Prove: PR SR

n¬ 89 30 25 20

n¬ 25 30

S

P

n¬ 25 30

T Q


5-5

Inequalities Involving Two Triangles

Pages 270–271


1. Sample answer: A pair of scissors illustrates the SSS inequality. As the distance between the tips of the scissors decreases, the angle between the blades decreases, allowing the blades to cut. 2. The SSS Inequality Theorem compares the angle between two sides of a triangle for which the two sides are congruent and the third side is different. The SSS Postulate states that two triangles that have three sides congruent are congruent. 3. In BDC and BDA, B C A D , B D B D , and mBDA mCBD. The SAS Inequality Theorem allows us to conclude that AB CD. 4. In PQS and RQS, R Q P Q , Q S Q S , and PS RS. The SSS Inequality Theorem allows us to conclude that mPQS mRQS. 5. The upper triangle is equilateral and so all angles are 60 degrees. The SAS inequality allows us to conclude that x 5 3x 7. x 5¬ 3x 7 5¬ 2x 7 12¬ 2x 6¬ x Also, the measure of any side is greater than 0. 3x 7¬ 0 3x¬ 7 x¬ 7 3 The two inequalities can be written as the compound inequality 7 3 x 6. 6. Because 12 8, the SSS Inequality allows us to conclude 140 7x 4. 140¬ 7x 4 136¬ 7x 13 6 7 ¬ x

Chapter 5

R

Proof: Statements

Reasons

1. P Q S Q

1. Given

2. Q R Q R


3. mPQR mPQS mSQR

3. Angle Addition Postulate

4. mPQR mSQR

4. Def. of inequality

5. PR SR

5. SAS Inequality

8. Given: TU U S ; U S S V Prove: ST UV

S

T

U

V

Proof: Statements

Reasons

1. T U U S , U S S V

1. Given

2. mSUT mUSV

2. Ext. Inequality Theorem 3. SAS Inequality

3. ST UV

9. Sample answer: The pliers are an example of the SAS inequality. As force is applied to the handles, the angle between them decreases causing the distance between them to decrease. As the distance between the ends of the pliers decreases, more force is applied to a smaller area.

Pages 271–273 Practice and Apply 10. From the figure, AB 9 and FD 6, so AB FD. 11. In BDC and FDB, F D D C , B D B D , and BC BF. The SSS Inequality allows us to conclude that mBDC mFDB. 12. In BFA and DBF, A B B D , B F B F , and AF FD. The SSS Inequality allows us to conclude that mFBA mDBF. 13. In ABD and CBD, B C B A , B D B D , and mABD mCBD. The SAS Inequality allows us to conclude that AD DC.

144

14. In ABO and CBO, A B C B , O B O B , and mCBO mABO. The SAS Inequality allows us to conclude that OC OA. 15. In ABC, A B C B so ABC is isosceles with base angles of measure 1 2 [180 (40 60)] or 40. mAOB ¬180 (mOAB mABO) ¬180 (40 60) ¬80 mAOD ¬180 mAOB ¬100 Therefore, mAOD mAOB. 16. By the SAS Inequality, 10 3x 2. 10¬ 3x 2 12¬ 3x 4¬ x or x 4 17. The triangle on the left is equilateral, so all angles have measure 60. Then by the SAS inequality, x 2 2x 8. x 2¬ 2x 8 2¬ x 8 10¬ x The measure of any side is always greater than 0. 2x 8¬ 0 2x¬ 8 x¬ 4 The two inequalities can be written as the compound inequality 4 x 10. 18. M C M C , so by the SSS Inequality m1 m2. 5x 20¬ 8x 100 20¬ 3x 100 120¬ 3x 40¬ x The measure of any angle is always greater than 0. 8x 100¬ 0 8x¬ 100 x¬ 12.5 The two inequalities can be written as the compound inequality 12.5 x 40. 19. RTV TRV, so RVT is isosceles and V R T V . S V S V and RS ST, so by the SSS Inequality, mRVS mSVT. 15 5x¬ 10x 20 15¬ 5x 20 35¬ 5x 7¬ x The measure of SVT is less than 180. 10x 20¬ 180 10x¬ 200 x¬ 20 The two inequalities can be written as the compound inequality 7 x 20.

20. Given: ABC, A B C D Prove: BC AD

B 2

A

1

D Proof: Statements

C Reasons

1. ABC, A B C D

1. Given

2. B D B D


3. m1 m2

3. If an is an ext. of a , then its measure is greater than the measure of either remote int. .

4. BC AD

4. SAS Inequality

21. Given: P Q R S , QR PS Prove: m3 m1

Q 1

R 2

P Proof: Statements 1. P Q R S

145

4

3

S Reasons 1. Given

QS Q S 2. 3. QR PS


4. m3 m1

4. SSS Inequality

3. Given

Chapter 5

22. Given: P R P Q , SQ SR Prove: m1 m2

P

S

1 4

R

3

2

Q

Proof: Statements

Reasons 11. Given

11. P R P Q 12. PRQ PQR

13. Angle Add. Post.

14. mPRQ mPQR 15. m1 m4 m2 m3 16. SQ SR

14. Def. of angles 15. Substitution

17. m4 m3

17. If one side of a is longer than another side, then the opposite the longer side is greater than the opposite the shorter side.

18. m4 m3 x


19. m1 m3 x m2 m3

19. Substitution

10. m1 x m2

10. Subtraction Prop.

11. m1 m2


1

D

16. Given

C

9. Substitution

10. AE EC AC, AF FB AB

10. Segment Add. Post.

11. AC AB

11. Substitution

U

T

1.67

0.78s 28. v ¬ 1.17

Proof: Statements

9. AE EC AF FB

h 0.78(1.0)1.67 ¬ 0.851.17

Reasons

1. ED D F ; D is the midpoint of D B .

1. Given

2. CD BD

2. Def. of midpoint

3. C D B D

3. Def. of segments

0.78(1.2) ¬ 1.17

4. m1 m2

4. Given

¬1.28 m/s

5. EC FB

5. SAS Inequality

6. A E A F

6. Given

Chapter 5

W

V

Indirect Proof: Step 1 Assume mS mW. Step 2 If mS mW, then either mS mW or mS mW. Case 1: If mS mW, then RT UV by the SAS Inequality. Case 2: If mS mW, then RST UWV by SAS, and R T U V by CPCTC. Thus RT UV. Step 3 Both cases contradict the given RT UV. Therefore, the assumption must be false, and the conclusion, mS mW, must be true. 25. As the door is opened wider, the angle formed increases and the distance from the end of the door to the door frame increases. 26. By the SAS Inequality Theorem, if the tree started to lean, one of the angles of the triangle formed by the tree, the ground, and the stake would change, and the side opposite that angle would change as well. However, with the stake in the ground and fixed to the tree, none of the sides of the triangle can change length. Thus, none of the angles can change. This ensures that the tree will stay straight. 27. As the vertex angle increases, the base angles decrease. Thus, as the base angles decrease, the altitude of the triangle decreases.

E 2

8. Add. Prop. of Inequality

S

A

B

8. AE EC AE FB

R

23. Given: ED D F ; m1 m2; D is the midpoint of C B ; A E A F . Prove: AC AB

F

7. Def. of segments

24. Given: R S ¬ U W T S ¬ W V RT¬ UV Prove: mS mW

12. If two sides of are , the angles opposite the sides are .

13. mPRQ m1 m4, mPQR m2 m3

7. AE AF

¬0.94 m/s 1.67

0.78s v ¬ 1.17 h

1.67

0.85

146

29.

39. Given: A D bisects B E ; A B D E . Prove: ABC DEC

1.67

Stride (m)

0.78s v 1.17

Velocity (m/s)

0.25

0.78(0.25)1.67 1.11.17

0.07

0.50

0.78(0.50)1.67 1.11.17

0.22

0.75

0.78(0.75)1.67 1.11.17

0.43

h

0.78(1.00)1.67

B

1.00

1.11.17

0.70

1.25

0.78(1.25)1.67 1.11.17

1.01

1.50

0.78(1.50)1.67 1.11.17

1.37

33. B;

4

C

A

E

Proof: Statements

30. As the length of the stride increases, the angle formed at the hip increases. 31. Sample answer: A backhoe digs when the angle between the two arms decreases and the shovel moves through the dirt. Answers should include the following. • As the operator digs, the angle between the arms decreases. • The distance between the ends of the arms increases as the angle between the arms increases, and decreases as the angle decreases. 32. B; AD BD by definition of a median. AC BC since m1 m2 and by the SAS Inequality. m1 mB because if an is an ext. of a , then its measure is greater than the measure of either remote int. . mADC m1 and mBDC m2, and m1 m2 is given, so mADC mBDC. The correct answer is B. 1(99.50 88.95 95.90 102.45) 2

D

Reasons

1. AD bisects B E ; B A D E .

1. Given

2. B C E C

2. Def. of seg. bisector

3. B E

3. Alt. int. Thm.

4. BCA ECD

4. Vert. are .

5. ABC DEC

5. ASA

M bisects LMN; L M M N . 40. Given: O Prove: MOL MON

N O M

L

Proof: Statements

Reasons

1. OM bisects LMN; M L M N .

1. Given

2. LMO NMO

2. Def. of bisector

M O M 3. O

3. Reflexive Prop.

4. MOL MON

4. SAS

41. EF ¬ (4 4 )2 (1 1 6)2 ¬ 0 25 or 5

48.35

2 (6 FG ¬ (9 4) 11)2

¬ 25 25 or 50


2 (6 EG ¬ (9 4) 6)2

34. no; 1 21 25 ? ? ? 35. yes; 16 6¬ 19 6 19¬ 16 16 19¬ 6 22¬ 19 ✓ 25¬ 16 ✓ 35¬ 6 ✓ 36. no; 8 7 15 37. A D is a not a median of ABC. 38. The triangle is not isosceles.

¬ 25 0 or 5 EFG is isosceles. 42. EF ¬ [15 (7)]2 (0 10)2 ¬ 484 100 or 584 FG ¬ (2 15)2 (1 0)2 ¬ 289 1 or 290 EG ¬ [2 (7)]2 ( 1 10 )2 ¬ 25 121 or 146 EFG is scalene. 43. EF ¬ (7 1 6)2 (6 1 4)2 ¬ 81 64 or 145 FG ¬ (5 7)2 (14 6)2 ¬ 144 400 or 544 EG ¬ (5 16)2 (14 14)2 ¬ 441 784 or 35 EFG is scalene.

147

Chapter 5

15. mQDR mRDS ¬180 mQDR 110 ¬180 mQDR ¬70 mQRD mQDR mRQD ¬180 mQRD 70 73 ¬180 mQRD ¬37 The angle opposite D Q has a smaller measure than the angle opposite D R , so DQ DR. 16. mQRP ¬37 (see exercise 15) mQPR ¬27 In PQR, the angle opposite P Q has a greater measure than the angle opposite Q R , so PQ QR. 17. mSRQ ¬mSRD mDRQ ¬34 37 ¬71 The angle opposite S R has a greater measure than the angle opposite S Q , so SR SQ. 18. 2 is a rational number. 19. The triangles are not congruent. 20. Assume that Miguel completed at most 20 passes in each of the five games in which he played. If we let p1, p2, p3, p4, and p5 be the number of passes Miguel completed in games 1, 2, 3, 4, and 5, respectively, then p1 p2 p3 p4 p5 ¬the total number of passes Miguel completed ¬101. Because we have assumed that he completed at most 20 passes in each of the five games, p1 20 and p2 20 and p3 20 and p4 20 and p5 20. Then, by a property of inequalities, p1 p2 p3 p4 p5 20 20 20 20 20 or 100 passes. But this says that Miguel completed at most 100 passes this season, which contradicts the information we were given, that he completed 101 passes. So our assumption must be false. Thus, Miguel completed more than 20 passes in at least one game this season.

44. EF ¬ (12 9)2 (14 9)2 ¬ 9 25 or 34 FG ¬ (14 12)2 (6 14) 2 ¬ 4 64 or 68 EG ¬ (14 9)2 (6 9)2 ¬ 25 9 or 34 EFG is isosceles. 45. Let p, q be the parts of the statement. p: it has to be special q: it has to be Wildflowers The statement p is true, so it follows that Catalina should go to Wildflowers by the Law of Detachment.

Chapter 5 Study Guide and Review Page 274 1. 2. 3. 4. 5. 6. 7.


incenter median Triangle Inequality Theorem centroid angle bisector perpendicular bisectors orthocenter

Pages 274–276


8. mACQ ¬mQCB mQCB ¬1 2 mACB 42 x ¬1 2 (123 x)

42 x ¬61.5 2x

42 3 2 x ¬61.5 3x ¬19.5 2

9.

10.

11. 12. 13. 14.

?

x ¬13 mACQ 42 13 or 55 AR RB 3x 6 ¬5x 14 6 ¬2x 14 20 ¬2x 10 ¬x AB ¬AR AB ¬3(10) 6 5(10) 14 ¬72 mAPC ¬90 72 x ¬90 x ¬18 The side opposite DEF is longer than the side opposite DFE, so mDEF mDFE. The side opposite GDF is shorter than the side opposite DGF, so mGDF mDGF. The side opposite DEF is longer than the side opposite FDE, so mDEF mFDE. The angle opposite S R has a greater measure than the angle opposite S D , so SR SD.

Chapter 5

21. no; 7 5 ¬20 12 ¬20 Because the sum of two measures is less than the third measure, the sides cannot form a triangle. 22. Check each inequality. ? ? ? 16 20¬ 5 16 5¬ 20 20 5¬ 16 36¬ 5 ✓ 21¬ 20 ✓ 25¬ 16 ✓ All of the inequalities are true, so 16, 20, and 5 can be the lengths of the sides of a triangle. 23. Check each inequality. ? ? ? 18 20¬ 6 18 6¬ 20 20 6¬ 18 38¬ 6 ✓ 24¬ 20 ✓ 26¬ 18 ✓ All of the inequalities are true, so 18, 20, and 6 can be the lengths of the sides of a triangle. 24. In BAM and DAM, A B A D , A M A M , and BM DM. The SSS Inequality allows us to conclude that mBAC mDAC. 25. In BMC and DCM, B M C D , M C M C , and mBMC mDCM. The SAS Inequality allows us to conclude that BC MD.

148

26. Using the SSS Inequality, 54 28 so 41 x 20 or 21 x. x 20 0, so x 20. The two inequalities can be written as the compound inequality 20 x 21. 27. In the upper triangle, the bottom angle has measure 90 60 or 30, so the upper left angle has measure 180 (95 30) or 55. Then by the SAS Inequality, 5x 3 3x 17. 5x 3¬ 3x 17 2x 3¬ 17 2x¬ 14 x¬ 7

But this says that Marcus spent less than one and one-half hours on a teleconference over the three days, which contradicts the information we were given. So we must abandon our assumption. Thus, Marcus spent at least one half-hour on a teleconference, on at least one of the three days. 13. Let the measure of the third side be n. 1 14¬ n 1 n¬ 14 14 n¬ 1 15¬ n or n 15 n¬ 13 n¬ 13 Graph the inequalities on the same number line. 15

12

9

6

3

0

3

6

9

12

15

18

12

9

6

3

0

3

6

9

12 13 15

18

9

6

3

0

3

6

9

12

15

18

9

6

3

0

3

6

9

12 13 15

18

n¬ 15 15


n¬ 13

Page 277

n¬ 13

1. 2. 3. 4.

5.

6.

7.

8. 9. 10. 11. 12.

15 13 12

b c a HP PJ 5x 16 ¬3x 8 2x 16 ¬8 2x ¬24 x ¬12 HJ ¬HP PJ ¬5(12) 16 3(12) 8 ¬88 mGJN ¬mNJH 6y 3 ¬4y 23 2y 3 ¬23 2y ¬26 y ¬13 mGJH ¬mGJN mNJH ¬6(13) 3 4(13) 23 ¬150 mHMG ¬90 4z 14 ¬90 4z ¬76 z ¬19 By the Exterior Angle Theorem, m8 m7 and m5 m8. By transitivity, m5 m7, so 5 has the greatest measure. By the Exterior Angle Theorem, m8 m7 and m8 m6, so 8 has the greatest measure. By the Exterior Angle Theorem, m1 m6 and m1 m9, so 1 has the greatest measure. 2n 1 is even. Alternate interior angles are not congruent. Assume that Marcus spent less than one half hour on a teleconference every day. If we let t1, t2, and t3 be the time spent on a teleconference on days 1, 2, and 3, respectively, then t1 t2 t3 the total amount of time over the three days spent on the teleconference. Because he spent less than a half hour every day on a teleconference, t1 0.5 and t2 0.5 and t3 0.5. Then, by a property of inequalities, t1 t2 t3 0.5 0.5 0.5 or 1.5 hours.

15

12


1

0

1

3

5

7

9

11

13

15

17 19

21

23

25

1

0

1

3

5

7

9

11

13

15

17 19

21

23

25

1

0

1

3

5

7

9

11

13

15

17 19

21

23

25

1

0

1

3

5

7

9

11

13

15

17 19

21

23

25

n¬ 25 3

n¬ 3 3

n¬ 3 3


4

0

4

8

12

16

20

24

28

32

36

4

0

4

6 8

12

16

20

24

28

32

36

0

4

8

12

16

20

24

28

32

36

0

4 6 8

12

16

20

24

28

32

36

n¬ 32 8

n¬ 6 8 6 4

n¬ 6 8

4

Find the intersection. The range of values that fit all three inequalities is 6 n 32. 16. y 0, so y 1 y. Then 7 x and x 0, so 0 x 7.

149

Chapter 5

x 7¬ 11 x¬ 4 7 11¬ 2x 18¬ 2x 9¬ x 4x9 18. In the two triangles, each has a side of measure 12 and the shared side is congruent to itself. The hypotenuse of the right triangle has a length of 13.86, which is shorter than the third length of the other triangle, 14. So the SSS Inequality allows us to conclude that x 90. In any triangle, an angle has measure less than 180, so we can write the compound inequality 90 x 180. 19. Let d be the distance between NewYork and Atlanta. 554 399¬ d 953¬ d or d 953 399 d¬ 554 d¬ 155 Therefore, 155 mi d 953 mi. 20. A; 3 8 11, so 3, 8, 11 cannot be the sides of a triangle.

7 11 20, so 7, 11, 20 cannot be the measures of the sides of the triangle. 9 13 26, so 9, 13, 26 cannot be the measures of the sides of the triangle. 9. The ramp rises 2 feet as it runs 24 feet, so the

17.

2 1 slope is 2 4 or 1 2. 10. x 55¬ 90 x¬ 35

11. The point P is the midpoint of B C with 8 2 10 8 coordinates 2 , 2 (8, 6).

(200 120)

20. Find slope again the line is (0 4) using one of the given points and (10, 0); the (120 0)

slope is (4 10) 20. Since the slope is the same, (10, 0) must be on the original line. Students may check by drawing an extension of the line and will see that it goes through (10, 0). 14b. The point (10, 0) shows that on the tenth payment Kendell’s balance will be $0, so the amount will be paid in full. 15a. y C (3, 4)

Chapter 5 Standardized Test Practice Pages 278–279 1. D; there are 36 inches in a yard, so there are 362 or 1296 square inches in a square yard. So there are 1296(80) or 103,680 yarn fibers in a square yard. 2. B; 6 7 6 4 12 11 46 units 3. B; the converse is false because if an angle is acute it can have any measure between 0 and 90. 4. B; A B

F

5. 6. 7. 8.

A (3, 1) x

B (0, 2) 2 15b. AB =¬ [0 (3)] (2 1)2 ¬ 99 ¬ 18 ¬4.2

C

BC ¬ (3 0 )2 [4 (2 )]2 ¬ 9 36 ¬ 45 ¬6.7 2 AC ¬ [3 (3)] (4 1)2 ¬ 36 9 ¬ 45 ¬6.7 15c. isosceles triangle because B C is congruent to A C 15d. According to the Isosceles Triangle Theorem, if two sides of a triangle are congruent, then the angles opposite those sides are congruent. Since C B A C , A B. 15e. If one side of a triangle is longer than another side, the angle opposite the longer side has a greater measure than the angle opposite the shorter side. Since B C is longer than A B , mA mC.

E D There are 6 people at the meeting. Let noncollinear points A, B, C, D, E, and F represent the 6 people. Connect each point with every other point. Between every two points there is exactly one segment. For the 6 points, 15 segments can be drawn. Thus 15 exchanges are made. B B; use indirect reasoning C; the shortest distance from a point to a line segment is a perpendicular segment ? ? ? A; 2 9¬ 10 2 10¬ 9 9 10¬ 2 11¬ 10 ✓ 12¬ 9 ✓ 19¬ 2 ✓ 5 8 13, so 5, 8, 13 cannot be the measures of the sides of the triangle.

Chapter 5

12. BC is vertical, so A T is horizontal. The y-coordinate of A is 4, and so the y-coordinate of T is also 4. T is on B C , so the x-coordinate of T is 8. Therefore the coordinates of T are (8, 4). 13. SSS Inequality 14a. From the points (0, 200) and (4, 120), the slope of

150

Chapter 6 Proportions and Similarity Page 281

Getting Started

6-1

1. 2 3 y 4 ¬6

2 y ¬10 3 y ¬3 2 (10) or 15 4 5 x ¬ 2. 12 6 4 x 12 5 6 ¬12 12

Pages 284–285 Check for Understanding 1. Cross multiply and divide by 28. 1 0 5 4 2. Sample answer: 5 4 8 , 10 8 3. Suki; Madeline did not find the cross products correctly.

10 ¬x 4 14 ¬x

number of goals

9 4. 12 or 3 : 4 number of games

y2 4 ¬ 3 y1

3.

Proportions

height of replica

10 in ches 5. ¬ 10 feet height of statue

4(y 1) ¬3(y 2) 4y 4 ¬3y 6 y 4 ¬6 y ¬10

10 in ches ¬ 120 inches 1 ¬ 12

2y

32 4. 4 ¬ y

6.

¬128 y2 ¬64 y ¬8

11 x ¬ 5 35

35x ¬5(11) 35x ¬55 11 x ¬ 7

2y2

(y y ) (x2 x1) 5 ¬ 01 3 6 ¬ 3

2 1 5. m ¬

7.

2.3 x 4 ¬ 3.7

2.3(3.7) ¬4x 8.51 ¬4x 2.1275 ¬x

¬2

8.

(y y ) (x2 x1) 3 (3) ¬ 2 ( 6) 0 ¬8

2 x 4 2 ¬5

5(x 2) ¬2(4) 5x 10 ¬8 5x ¬18 x ¬3.6 9. Rewrite 9 : 8 : 7 as 9x : 8x : 7x and use those measures for the sides of the triangle. Write an equation to represent the perimeter of the triangle as the sum of the measures of its sides. 9x 8x 7x ¬144 24x ¬144 x ¬6 Use this value of x to find the measures of the sides of the triangle. 9x 9(6) or 54 units 8x 8(6) or 48 units 7x 7(6) or 42 units 10. Rewrite 5 : 7 : 8 as 5x : 7x : 8x and use those measures for the angles of the triangle. Write an equation to represent the sum of the angle measures of the triangle. 5x 7x 8x ¬180 20x ¬180 x ¬9 Use this value of x to find the measures of the angles of the triangle. 5x 5(9) or 45 7x 7(9) or 63 8x 8(9) or 72

2 1 6. m ¬

¬0 (y y ) (x2 x1) 2 4 ¬ 2 ( 3) ¬6 5

2 1 7. m ¬

8. yes; congruent alternate exterior angles 9. yes; congruent alternate interior angles 10. No; 5 and 3 do not have a relationship that could be used to determine whether the lines are parallel. 11. 21 2 22 4 23 8 24 16 12. 12 2 1 2 1 22 2 4 2 2 32 2 9 2 7 42 2 16 2 14 13. 31 2 3 2 1 32 2 9 2 7 33 2 27 2 25 34 2 81 2 79

151

Chapter 6

scale on map (cm) distance represented (mi)

21. Rewrite 3 : 4 : 5 as 3x : 4x : 5x and use those measures for the sides of the triangle. 3x 4x 5x ¬72 12x ¬72 x ¬6 Use this value of x to find the measures of the sides of the triangle. 3x 3(6) or 18 in. 4x 4(6) or 24 in. 5x 5(6) or 30 in.

distance on map (cm) actual distance (mi)

11. ¬ 1.5 2.4 20 0 ¬x

1.5x ¬200(2.4) 1.5x ¬480 x ¬320 The cities are 320 miles apart.

Pages 285–287

Practice and Apply

1 1 x x x 22. Rewrite 1 2 : 3 : 5 as 2 : 3 : 5 and use those measures for the sides of the triangle.

8 number of hits 12. number of games 1 0 or 4 : 5

x x x ¬6.2 2 3 5 30 2x 3x 5x ¬30(6.2)

number of boys

76 or 76 : 89 13. 165 76 number of girls

20 8 number of rands 14. number of dollars 18 or 104 : 9

15x 10x 6x ¬186 31x ¬186 x ¬6 Use this value of x to find the measures of the sides of the triangle. x 6 2 2 or 3 cm

44,125 number of students 15. or about 25.3 : 1 number of teachers 1747 A C 2 0 0 16. BH 70 10 20 60 or 1 : 3

17. Rewrite 3 : 4 as 3x : 4x and use those measures for the two lengths of cable. 3x 4x ¬42 7x ¬42 x ¬6 Use this value of x to find the measures of the two lengths of cable. 3x 3(6) or 18 ft 4x 4(6) or 24 ft 18. Rewrite 2 : 5 : 3 as 2x : 5x : 3x and use those measures for the angles of the triangle. 2x 5x 3x ¬180 10x ¬180 x ¬18 Use this value of x to find the measures of the angles of the triangle. 2x 2(18) or 36 5x 5(18) or 90 3x 3(18) or 54 19. Rewrite 6 : 9 : 10 as 6x : 9x : 10x and use those measures for the angles of the triangle. 6x 9x 10x ¬180 25x ¬180 x ¬7.2 Use this value of x to find the measures of the angles of the triangle. 6x ¬6(7.2) or 43.2 9x ¬9(7.2) or 64.8 10x ¬10(7.2) or 72 20. Rewrite 8 : 7 : 5 as 8x : 7x : 5x and use those measures for the sides of the triangle. 8x 7x 5x ¬240 20x ¬240 x ¬12 Use this value of x to find the measures of the sides of the triangle. 8x 8(12) or 96 ft 7x 7(12) or 84 ft 5x 5(12) or 60 ft

Chapter 6

x 6 or 2 cm 3 3 x 6 5 5 or 1.2 cm height of the door 15 3 23. 10 or 2 Alice’s height in Wonderland height of the door Alice’s height in Wonderland

24. height of door in Alice’s normal world Alice’s normal height 15 x ¬ 50 10

¬

15(50) ¬10x 750 ¬10x 75 ¬x The height of the door in Alice’s normal world would be about 75 inches. Lincoln’s height in model

8 i n. 25. ¬ 6 ft 4 in. Lincoln’s height in theater 8 in. ¬ 76 in.

¬2 : 19 number of people in United States number of pounds of ice cream consumed

26. number of people in Raleigh, NC number of pounds of ice cream

¬ 255,082,000 276,000 4,183,3 44,800 ¬x

255,082,000x ¬1,154,603,165,000,000 x ¬4,526,400 The people of Raleigh, North Carolina, might consume 4,526,400 pounds of ice cream. number of people in United States number of pounds of ice cream consumed 1 person ¬ number of pounds of ice cream 255,082,000 1 4,183,3 44,800 ¬x

27.

255,082,000x ¬4,183,344,800 x ¬16.4 One person consumed about 16.4 pounds of ice cream.

152

28.

x 3 ¬5 8

38c. The ratio 4 : 5 : 4 : 5 indicates that there are four sides, and opposite sides are congruent. This description fits a rectangle or a parallelogram. 39. Sample answer: It appears that Tiffany used rectangles with areas that were in proportion as a background for this artwork. Answers should include the following. • The center column pieces are to the third column from the left pieces as the pieces from the third column are to the pieces in the outside column. • The dimensions are approximately 24 inches by 34 inches.

3(5) 8x 15 ¬8x 15 8 ¬x a ¬1 29. 5.18 4

4a ¬5.18(1) a ¬1.295

30.

3x 48 2 3 ¬ 92

3x(92) ¬23(48) 276x ¬1104 x ¬4 31.

13 2 6 49 ¬ 7x

1.6 18 12 40. 1 ¬ x

13(7x) ¬49(26) 91x ¬1274 x ¬14 32.

1.618x¬ 12 x ¬7.4 cm 41. D; the ratio of wheat to rice to oats is 3 : 1 : 2, so the ratio of wheat to oats is 3 : 2.

13 4 2x ¬ 28 7

(2x 13)(7) ¬28(4) 14x 91 ¬112 14x ¬21 x ¬3 2 33.

3 ¬x 120 2

3(120) ¬2x 360 ¬2x 180 ¬x 180 pounds of wheat will be used. The answer is D.

3 4x ¬5 12 4

(4x 3)(4) ¬12(5) 16x 12 ¬60 16x ¬48 x ¬3 34.

Page 287

m1 m2 ¬180 3x 50 x 30 ¬180 4x 20 ¬180 4x ¬200 x ¬50 m1 ¬3(50) 50 ¬150 50 or 100 m2 ¬50 30 or 80 So, m1 m2, and by the SAS Inequality LS SN. 43. Always; PNO is an exterior angle of SNO, so mPNO m2. Then by the SAS Inequality, OP SN. 44. never; m1 m2 ¬180 3x 50 x 30 ¬180 4x 20 ¬180 4x ¬200 x ¬50 45. Let the measure of the third side be x. 16 31 ¬x 16 x ¬31 31 x ¬16 47 ¬x or x 47 x ¬15 x ¬15 Graph the inequalities on the same number line.

1 b 5 b 1 ¬ 6

(b 1)(6) ¬(b 1)(5) 6b 6 ¬5b 5 b 6 ¬5 b ¬11 35.


42. always;

3x 1 2 2 ¬ x 2

(3x 1)(x 2) ¬4 3x2 6x x 2 ¬4 3x2 5x 2 ¬0 (3x 2)(x 1) ¬0 3x 2 ¬0 or x10 3x ¬2 x 1 2 x ¬ 3 36. The larger dimension of the photograph is 27.5 cm, so reducing this dimension to 10 cm will give the maximum dimensions of the reduced photograph. 27 .5 21 .3 10 ¬ x

27.5x ¬10(21.3) 27.5x ¬213 x ¬7.75 The maximum dimensions are 7.75 cm by 10 cm.

15

10

5

0

5

10

15

20

25

30

35

40

45 47 50

5

0

5

10

15

20

25

30

35

40

45

50

5

0

5

10

15

20

25

30

35

40

45

50

5

0

5

10

15

20

25

30

35

40

45 47 50

x 47

reduced length 7.7 5 37. 21.3 original length

15

0.36 or 36% 38a. The ratio 2 : 2 : 3 indicates that there are three sides, two of which have the same measure. This description fits an isosceles triangle. 38b. The ratio 3 : 3 : 3 : 3 indicates that there are four sides with all the same measure. This description fits a square or a rhombus.

10

x 15 15

10

x 15 15

153

10

Chapter 6

2 (3 YZ (6 4) 3)2 22 02 4 or 2 SU (2 0)2 (0 5)2 (2)2 (5)2 29 2 (3 XZ (6 4) 8)2 2 2 2 ( 5) 29 STU XYZ by SSS. 49. Start at P(3, 4). Move up 3 units and then move right 5 units. Draw the line through this point and P.

Find the intersection. The range of values that fit all three inequalities is 15 x 47. 46. Let the measure of the third side be x. 26 40 ¬x 26 x ¬40 40 x ¬26 66 ¬x or x 66 x ¬14 x ¬14 Graph the inequalities on the same number line. 20

10

0

10

20

30

40

50

60 66 70

80

90

0

10 14 20

30

40

50

60

70

80

90

0

10

20

30

40

50

60

70

80

90

0

10 14 20

30

40

50

60 66 70

80

90

x 66 20

10

x 14 20 14 10

y

x 14 20

10

x

O

Find the intersection. The range of values that fit all three inequalities is 14 x 66. 47. Let the measure of the third side be x. 11 23 ¬x 11 x ¬23 23 x ¬11 34 ¬x or x 34 x ¬12 x ¬12 Graph the inequalities on the same numer line.

P( 3, 4)

. 50. Plot points A(5, 3) and B(1, 8). Draw line AB y

B ( 1, 8)

15

10

5

0

5

10

15

20

25

30 34 35

40

5

0

5

10 12 15

20

25

30

35

40

5

0

5

10

20

25

30

35

40

x 34 15

10

A(5, 3)

x 12 x

O 15 12 10

15

51. Find the slope of JK.

x 12 15

10

(y y ) (x2 x1) 3 5 ¬ 4 ( 1) 2 ¬ 5

2 1 m ¬

5

0

5

10 12 15

20

25

30 34 35

40

Find the intersection. The range of values that fit all three inequalities is 12 x 34. 48.

The line through E(2, 2) also has slope 2 5. Start at E(2, 2). Move down 2 units and then move right 5 units. Draw the line through this point and E.

12 y

X (4, 8) 8 S (0, 5) Z (6, 3) 4 Y (4, 3) x U (2, 0) 12 8

4 T (0, 0) 4 4

8

y

E (2, 2)

12 O

8

x

12 2 (0 ST (0 0) 5)2 02 ( 5)2 25 or 5 2 (3 XY (4 4) 8)2 2 2 0 (5) 25 or 5 TU (2 0)2 (0 0)2 2 2 (2) 0 4 or 2

52. Find the slope of QR. (y y ) (x2 x1) 6 2 ¬ 4 6 8 4 ¬ 1 0 or 5

2 1 m ¬

The product of the slopes of two perpendicular lines is 1. 5 Since 4 5 4 1, the slope of the line QR through S(8, 1) is 5. perpendicular to 4

Chapter 6

154

Start at S(8, 1). Move down 5 units and then move right 4 units. Draw the line through this point and S.

2. See students’ drawings. Sample counterexample: A rectangle with consecutive sides of 4 in. and 12 in. would not have sides proportional to a rectangle with consecutive sides of 6 in. and 8 in. 12 because 4 6 8 . 3. If two polygons are congruent, then they are similar. All of the corresponding angles are congruent, and the ratio of measures of the corresponding sides is 1. Two similar figures have congruent angles, and the sides are in proportion, but not always congruent. If the scale factor is 1, then the figures are congruent. 4. PQR and GHI each have two angles with measure 60, so the third angle of each triangle must also have measure 60. Thus, P Q R

y

S (8, 1) x

O

53. Yes; 100 km and 62 mi are the same length, so AB CD. By the definition of congruent segments, A B C D . 2 54. d ¬(x x ) (y2 y1)2 2 1

PQ

AD CB 4 2 EH GF 6 or 3 DC B A 3 or 2 H G FE 3 9 2

2 (1 CD ¬ (5 0) 2 0)2 2 2 ¬ 5 12 ¬169 or 13.0 56. d ¬ (x2 x1)2 (y2 y1)2

The ratios of the measures of the corresponding sides are equal, and the corresponding angles are congruent, so parallelogram ABCD parallelogram EFGH. 6. Use the congruent angles to write the corresponding vertices in order: ACB DFE. Write a proportion to find x.

1 (1) 2 45 2 2

EF ¬

57.

2

¬ 1.22 0.52 ¬1.69 or 1.3 d ¬ (x2 x1)2 (y2 y1)2

AC C B D F ¬ FE 21 27 x ¬ 18

5 ¬1 7

GH ¬ (4

3)2

2

3 2 7 7

2

2

21(18) ¬27x 378 ¬27x 14 ¬x So, DF 14. AC 21 3 The scale factor is D F 14 or 2 . 7. Use the congruent angles to write the corresponding vertices in order: polygon ABCD polygon EFGH. Write a proportion to find x.

25 ¬ 1 49 74 ¬ 49

¬1.2

DA B A HE ¬ FE 10 14 x 3 ¬ x 5

Page 288 Spreadsheet Investigation: Fibonacci Sequence and Ratios 1. 2. 3. 4.

It increases also. odd-odd-even It approaches 1.618. The increase in terms confirms the original observations. 5. As the number of terms increases, the ratio of each term to its preceding term approaches the golden ratio.

6-2

QR

R P 3 G H I and GH HI IG 7 , so PQR GHI. 5. From the diagram, A E, B F, C G, and D H.

AB ¬ (8 12)2 (3 3 )2 2 2 ¬ (20) 0 ¬400 or 20.0 55. d ¬ (x2 x1)2 (y2 y1)2

10(x 5) ¬(x 3)(14) 10x 50 ¬14x 42 10x 92 ¬14x 92 ¬4x 23 ¬x EF x 5 23 5 or 28 EH x 3 23 3 or 20 E F G F CB AB G F 28 16 14 G F 2, so GF 2(16) or 32. 16 DA 10 1 The scale factor is H E 20 or 2 .

Similar Polygons

Pages 292–293 Check for Understanding 1. Both students are correct. One student has inverted the ratio and reversed the order of the comparison.

155

Chapter 6

8. Write proportions for finding side measures.

DB 2 3 MP 513 or 8 B C 4 3 PN 1023 or 8 CD 3 NM 8

new length → x 1 original length → 60 4

4x ¬60 x ¬15

new height → y 1 original height → 40 4

The ratios of the measures of the corresponding sides are equal, and the corresponding angles are congruent, so BCD PNM.

4y ¬40 y ¬10 The new length is 15 cm, and the new height is 10 cm. 9. Write proportions for finding side measures.

2

3503 feet

height of replica

15. 1052 feet height of actual tower 1 3

The scale factor is 1 3. 8 16. The first copy is 80% or 10 of the original. The second copy must be 100% or 1 of the original.

new first side → x 5 original first side → 3

x 15 new second side → y 5 original second side → 5

1 second copy 8 first copy 10

y 25

1 0 8 1.25 Use a scale factor of 1.25 or 125%. 17. Use the congruent angles to write the corresponding vertices in order: polygon ABCD polygon EFGH. Write a proportion to find x.

new third side → z 5 original third side → 4

z 20 The new side lengths are 15 m, 25 m, and 20 m, so the perimeter is 15 m 25 m 20 m 60 m. 10. See students’ drawings. The drawings will be similar since the measures of the corresponding sides will be proportional and the corresponding angles will be congruent.

CD AB EF ¬ GH 1 1 x x 8 ¬5

(x 1)(5) ¬8(x 1) 5x 5 ¬8x 8 5 ¬3x 8 13 ¬3x

6.56 cm

1 3 3 ¬x

AB x 1 1 3 1 6 3 1 or 3 CD x 1

Figure is not shown actual size.

1 3 1 0 3 1 or 3 1 6

Pages 293–297

3 A B 2 The scale factor is EF 8 or 3 . 18. Use the congruent angles to write the corresponding vertices in order: ABC EDC. Write a proportion to find x.

Practice and Apply

11. BCF DCF, ABC EDC, BAF DEF, and AFC EFC; B C D C , A B E D ; F A E F , and C F C F . Therefore, ABCF is similar to EDCF since they are congruent. 12. 1 2 3 4; 6 5 because if two angles of one triangle are congruent to two angles of a second triangle, then the third angles are congruent. X Y X W X Z , and Y W W Z , so the ratio of the corresponding sides is 1. Therefore, XYW XWZ. 13. ABC is not similar to DEF. From the lengths of the sides we can determine that A corresponds to D, but A D. 14. B P, D M, and C N because if two angles of one triangle are congruent to two angles of a second triangle, then the third angles are congruent.

Chapter 6

AC C B E C ¬ CD x 7 4 12 x ¬ 6

(x 7)(6) ¬(12 x)(4) 6x 42 ¬48 4x 10x 42 ¬48 10x ¬6 x ¬3 5 AC x 7 3 3 5 7 or 7 5 CE 12 x 2 12 3 5 or 11 5 C B 2 The scale factor is 4 CD 6 or 3 .

156

19. Use the congruent angles to write the corresponding vertices in order: ABE ACD. Write a proportion to find x.

22. The enlargement process E can be represented by

5 the equation E 5 4 4x . 25 5 23. 5 4 4 16 24. Explore: Every millimeter represents 1 meter. The dimensions of the field are about 69 meters by 105 meters. Plan: Create a proportion relating each measurement to the scale to find the measurements in millimeters. Then make a scale drawing. Solve:

AE AB AC ¬ AD 6.25 10 10 x 2 ¬ 6.25 x 1 10 6.2 5 ¬ x 12 x 5.25

10(x 5.25) ¬(x 12)(6.25) 10x 52.5 ¬6.25x 75 3.75x 52.5 ¬75 3.75x ¬22.5 x ¬6 BC x 2 6 2 or 8 ED x 1 6 1 or 5 AB 10 AB The scale factor is AC AB BC 10 8

millimeters → 1 x ← millimeters meters → 1 69 ← meters

69 x The width of the field should be 69 millimeters in the drawing. millimeters → 1 y ← millimeters meters → 1 105 ← meters

10 5 18 or 9 .

105 y The length of the field should be 105 millimeters in the drawing.

20. Use the congruent angles to write the corresponding vertices in order: RST EGF. Write a proportion to find x.

105 mm

ST R T EF ¬ GF 1 5 1 0 ¬ 11.25 x

69 mm

15x ¬11.25(10) 15x ¬112.5 x ¬7.5 GF x 7.5


Examine: The scale is 1 : 1, so it is clear that the dimensions in the drawing are reasonable. 25. Explore: Every 1 4 inch represents 4 feet. The dimensions of the basketball court are 84 feet by 50 feet. Plan: Create a proportion relating each measurement to the scale to find the measurements in inches. Then make a scale drawing. Solve:

EG G F SR ¬ ST EG 7. 5 20 .7 ¬ 10

(EG)(10) ¬(20.7)(7.5) (EG)(10) ¬155.25 EG ¬15.525 ST 10 4 The scale factor is GF 7.5 or 3 . 21. Write proportions for finding side measures.

inches →

1 x ← inches 4 feet → 4 84 ← feet 1(84) ¬4x 4

first new length →

x 5 original length → 2.5 4

21 ¬4x 5.25 ¬x The length of the court should be 5.25 inches in the drawing.

4x ¬2.5(5) 4x ¬12.5 x ¬3.125

second new length →

y 5 first new length → 3.125 4

1 y ← inches 4 feet 4 50 ← feet 1(50) ¬4y 4

inches

4y ¬3.125(5) 4y ¬15.625 y ¬3.9

12.5 ¬4y 3.125 ¬y The width of the court should be 3.125 inches in the drawing.

first new width → z 5 original width → 4 4

4z ¬4(5) 4z ¬20 z ¬5

5 1–4 in.

second new width → w 5 first new width → 5 4

3 1–8 in.

4w ¬5(5) 4w ¬25 w ¬6.25 After both enlargements the dimensions were about 3.9 inches by 6.25 inches.


Examine: The scale is 1 4 : 4. The dimensions in the drawing are reasonable.

157

Chapter 6

26. Explore: Every 1 8 inch represents 1 foot. The dimensions of the tennis court are 36 feet by 78 feet. Plan: Create a proportion relating each measurement to the scale to find the measurements in inches. Then make a scale drawing. Solve:

35.

1 x ← inches 8 ¬ feet → 1 36 ← feet 1 (36) ¬x 8

inches →

36.

4.5 ¬x The width of the court should be 4.5 inches in the drawing.

BC AB FE ¬ EH 2 8 x 1 5 ¬ 1 0

(x 2)(10) 15(8) 10x 20 ¬120 10x ¬100 x ¬10

1 y ← inches 8 feet → 1 78 ← feet 1(78) ¬y 8

inches →

D C BC ¬ GH EH y3 8 ¬ 1 0 5

9.75 ¬y The length of the court should be 9.75 inches in the drawing.

(y 3)(10) ¬5(8) 10y 30 ¬40 10y ¬70 y ¬7

9 3–4 in. 4 1–2 in.

37.

3 x 12 16 ¬8

(x 3)(8) ¬16(12) 8x 24 ¬192 8x ¬216 x ¬27

Figure is not shown actual size. Examine: The scale is 1 8 : 1. The dimensions in

the drawing are reasonable. 27. Always; the corresponding angles are congruent and the ratios of the measures of the corresponding sides are all 1. 28. Always; all angles are right angles and so all are congruent, and the ratios of the measures of the corresponding sides are all the same. 29. Never; the number of angles and sides of the figures must be the same for the figures to be compared. 30. sometimes; true when corresponding angles are congruent and ratios of measures of corresponding sides are equal, false when one of these does not hold 31. sometimes; true when the ratios of the measures of the corresponding sides are equal, false when they are not. 32. sometimes; true when corresponding angles are congruent and ratios of measures of corresponding sides are equal, false when one of these does not hold 33. Always; all angles have measure 60 and are congruent, and the ratios of the measures of the corresponding sides are all the same. 34. G ¬L mG ¬mL 87 ¬x 4 91 ¬x J ¬O mJ ¬mO y 30 ¬60 y ¬30

Chapter 6

L ¬S mL ¬mS 30 ¬x K ¬R mK ¬mR mK ¬180 (mQ mS) y ¬180 (80 30) y ¬180 110 y ¬70

y1 12 ¬8 10

(y 1)(8) ¬10(12) 8y 8 ¬120 8y ¬112 y ¬14 38.

2x 20 1 2 ¬ 15

2x(15) ¬12(20) 30x ¬240 x ¬8

y4 15 ¬ 20 12

(y 4)(20) ¬12(15) 20y 80 ¬180 20y ¬100 y ¬5 RS T S 39. W U ¬ VW x 49 2 9 ¬ 20

20x ¬29(49) 20x ¬1421 x ¬71.05 RT T S U V ¬ VW y3 49 ¬ 20 21

(y 3)(20) ¬21(49) 20y 60 ¬1029 20y ¬969 y ¬48.45 12 12 AD 8 40. AG 12 4.5 7.5 5

158

41. AG AD GD 12 4.5 7.5 42.

Sides opposite 23º angle. 12.5 PR 2.5 5 NM

The ratios of the measures of the corresponding sides are equal, and the corresponding angles are congruent, so NMO PRS.

D C AD GF ¬ AG 1 2 D C ¬ 14 7. 5

49.

7.5(DC) 14(12) 7.5(DC) 168 DC ¬22.4

8 4

43. mADC mAGF 108 44.

N 8

x

12

8

DA 4 and MN 8 so the scale factor is 8 4 or 2. To move from point A to point B, move up 4 units and then move 2 units to the right. Because the scale factor is 2, to move from N to L, move up 8 units and move 4 units to the right. So the coordinates of L could be (16, 8). Similarly the coordinates of P could be (8, 8) Another similar polygon can be obtained by moving down and to the right. To move from N to L, move down 8 units and move 4 units to the right. So the coordinates of L could also be L(16, 8). The coordinates of P could be (8, 8).

AG AE AB ¬ AD A E 7 . 5 2 6 ¬ 12

12(AE) ¬26(7.5) 12(AE) ¬195 AE ¬16.25 AE EF FG AG 16.25 8 14 7.5 45.75 73 .2 8 47. 45.7 5 5

50. 8

48. ABC IHG JLK and NMO PRS; A I J because each one measures 53º. B H L because each one is a right angle. C G K because each one measures 90º-53º or 37º. So all corresponding angles are congruent. Now determine whether corresponding sides are proportional. Sides opposite 90º angle. AC 5 4 JK 1.25 BC 4 4 LK 1

B A

C

M

8

O

4

D

4

8x

4 8

AD [2 (7)]2 ( 4 1)2 2 2 5 (5) 50 or 52

IG 10 8 JK 1.25

1 1 7 1 (3 ) 2 2 5 5 2 2 2

NM

HG 8 8 LK 1

2

Sides opposite 37º angle. AB 3 4 JL 0.75

y

4

N

Sides opposite 53º angle.

AB 3 1 IH 6 2

M 4

4

45. AB BC CD AD 26 12.8 22.4 12 73.2

4 1 BC 8 2 HG

B

O A

B C AD EF ¬ AG 1 2 B C 8 ¬ 7. 5

AC 1 5 IG 2 10

C

D

7.5(BC) 8(12) 7.5(BC) 96 BC ¬12.8 46.

y

IH 6 8 JL 0.75

2

2

5 0 5 4 or 2 2 52 M N 2 The scale factor is 1 AD 2. 52

The ratios of the measures of the corresponding sides are equal, and the corresponding angles are congruent, so ABC IHG, ABC JLK, and IHG JLK. N P because each one measures 67º. M R because each one is a right angle. O S because each one measures 90º-67º or 23º. So all corresponding angles are congruent. Now determine whether corresponding sides are proportional. Sides opposite 90º angle.

To move from point A to point B, move up 4 units and then move 9 units to the right. Because the scale factor is 1 2 , to obtain L from N move up 2 units and then move 4.5 units to the right. So the

3 coordinates of P could be 2, 3.

1 1 coordinates of L could be 1, 2 . Similarly, the

Another similar polygon can be obtained by moving down and to the left. To move from N to L move down 2 units and then move 4.5 units to the

32.5 PS 2.5 13 NO

left. So the coordinates of L could be 10, 3 2 .

Sides opposite 67º angle. 30 RS 2.5 12 MO

1 5 Similarly, the coordinates of P could be 2 , 1 .

159

Chapter 6

3

62. B; rewrite 5 : 3 as 5x : 3x. 5x 3x ¬32 8x ¬32 x ¬4 5x 5(4) or 20 3x 3(4) or 12 There are 20 12 or 8 more girls than boys. The answer is B. 63. D; 180 (51 85) 44 180 (51 44) 85 Corresponding angles are congruent. 12 9. 3 4 3 and 3.1 3, so the ratios of two pairs of corresponding sides are equal, so the triangles are similar.

4 inch 1 in ch 51. 24 fe et ¬

x feet

x ¬24 3 4 x ¬18 5

inch 8 1 in ch 24 feet ¬ y feet

y ¬24 5 8

y ¬15 The living room has dimensions 18 feet by 15 feet. 1 14 inches 1 in ch 52. 24 fe et x feet x 24(1.25) x 30

9. 3 x ¬ 2.8 3.1

3 8

inch 1 in ch 24 feet y feet

3.1x ¬2.8(9.3) 3.1x ¬26.04 x ¬8.4 The answer is D.

y 24 3 8 y9 The deck has dimensions 30 feet by 9 feet. 53. The sides are in a ratio of 4 : 1, so if the length of WXYZ is x then the length of ABCD is 4x, and if the width of WXYZ is y then the width of ABCD is (4x)(4y)

64. Multiply each coordinate by 2. A has coordinates (0 2, 0 2) (0, 0). B has coordinates (8 2, 0 2) (16, 0). C has coordinates (2 2, 7 2) (4, 14). 65. y C

16xy

4y. Then the areas are in a ratio of xy xy or 16 : 1.

12

4(3) 12 4 54. 4 1 1(3) 3 or 1 . The ratio is still 4 : 1. 55. The ratio of the areas is still 16 : 1 since the ratio of the sides is still 4 : 1. 56. No; the corresponding sides are not in proportion. The ratio of the widths is 1 to 1 but the ratio of the heights is 2 to 1. 57. The widths are the same but the height of the 36% rectangle is twice the height of the 18% w 2 rectangle, so the ratio of the areas is w or 2 : 1.

8 4

B

B AA 66.

36 % 0.3 6 The ratio of the percents is 18% 0.18 or 2 : 1, so the ratios are the same. 58. Sample answer: The difference between increase and decrease is 8%, so the level of courtesy is only slightly decreased. a b c 1 3a 3b 3c 3 a b c a b c 1 3a 3b 3c 3(a b c) 3 a 6 c 6 60. 3a 6 3c 6

59.

The sides are no longer proportional, so the new triangles are not similar. 61. Sample answer: Artists use geometric shapes in patterns to create another scene or picture. The included objects have the same shape but are different sizes. Answers should include the following. • The objects are enclosed within a circle. The objects seem to go on and on. • Each “ring” of figures has images that are approximately the same width, but vary in number and design.

Chapter 6

C

4

8

12

2 (0 AB ¬ (8 0) 0)2 2 2 ¬ 8 0 ¬64 or 8 A B (16 0)2 (0 0)2 2 2 16 0 256 or 16 2 (7 BC ¬ (2 8) 0)2 ¬ (6)2 72 ¬85 2 B C (4 16) (14 0)2 (12)2 142 340 or 285 2 (7 AC ¬ (2 0) 0)2 2 2 2 7 53 2 (1 A C (4 0) 4 0)2 2 2 4 1 4 212 or 253

AB 8 1 67. A B 16 or 2 AC 5 3 or 1 A C 2 2 53 BC 8 5 or 1 B C 2 2 85

160

16x

83. m2 m5 180 (supplementary consecutive interior ) 62 m5 180 m5 118 84. mABD m1 ( corresponding ) 118 85. m6 m4 180 (supplementary consecutive interior ) m6 118 180 m6 62 86. m7 m6 ( alternate interior ) 62 87. m8 m4 ( corresponding ) 118

68. You could use the slope formula to find that C B B C . Thus, ABC A B C and ACB A C B because of corresponding angles. A A because of the Third Angle Theorem. 69. The sides are proportional and the angles are congruent, so the triangles are similar.

Page 297


b 2 70. 7.8 ¬ 3

3b ¬7.8(2) 3b ¬15.6 b ¬5.2

71.

c 2 5 c 3 ¬ 4

(c 2)(4) ¬(c 3)(5) 4c 8 ¬5c 15 c 8 ¬15 c ¬23 c ¬23

6-3

Similar Triangles

Page 298 Geometry Activity: Similar Triangles

2 4 72. 4y 5 ¬ y

FD 4 1. ST 7 0.57 EF 2. 5 R S 4.4 0.57 ED 4. 3 RT 7.6 0.57

2y ¬(4y 5)(4) 2y ¬16y 20 18y ¬20

All of the ratios equal about 0.57. 2. Yes, all sides are in the same ratio. 3. Sample answer: Either all sides proportional or two corresponding angles congruent.

10 y ¬ 9

73. BC B A , B O B O , and mOBC mOBA. By the SAS Inequality, OC AO. 74. ABC is isosceles with base angles 1[180 (68 40)] 36. Then mAOB 180 2 (40 36) 104 and mAOD 180 104 76 so, mAOD mAOB. 75. mABD mADB because if one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. 76. x 52 35 180 x 93 77. x 32 57 180 x 91 78. x 40 25 180 x 115 79. m1 ¬m2 10x 9 ¬9x 3 x 9 ¬3 x ¬12 m1 10(12) 9 120 9 or 111 m2 9(12) 3 108 3 or 111 80. m1 m4 ( alternate interior ) 118) 81. m2 m4 180 (supplementary consecutive interior ) m2 118 180 m2 62 82. m3 m4 180 (linear pair) m3 118 180 m3 62

Page 301


1. Sample answer: Two triangles are congruent by the SSS, SAS, and ASA Postulates and the AAS Theorem. In these triangles, corresponding parts must be congruent. Two triangles are similar by AA similarity, SSS Similarity, and SAS Similarity. In similar triangles, the sides are proportional and the angles are congruent. Congruent triangles are always similar triangles. Similar triangles are congruent only when the scale factor for the proportional sides is 1. SSS and SAS are common relationships for both congruence and similarity. 2. Yes; suppose RST has angles that measure 46°, 54°, and 80°, ABC has angles that measure 39°, 63°, and 78°, and EFG has angles that measure 39°, 63°, and 78°. So ABC is not similar to RST and RST is not similar to EFG, but ABC is similar to EFG. 3. Alicia; while both have corresponding sides in a ratio, Alicia has them in proper order with the numerators from the same triangle. 4. A D and F C, so by AA Similarity, ABC DEF. FE D E AB ¬ CB 3 x 4 5 ¬ 1 5

15x ¬45(3) 15x ¬135 x ¬9 DE x 9

161

Chapter 6

5. A D and B E, so by AA Similarity, ABC DEF.

Pages 302–305 Practice and Apply 10. If the measures of the corresponding sides are proportional, then the triangles are similar.

AB B C D E ¬ EF x 5 x 4 3

QR QP R P 10 15 7 or 1, or 1, or 1 NO 21 3 NM 30 3 OM 45 3 QR QP R P , so by SSS Similarity, NO NM OM

3x ¬5(x 4) 3x ¬5x 20 2x ¬20 x ¬10 AB x 10 DE x 4 10 4 or 6

MNO PQR. 11. If the measures of the corresponding sides are proportional, then the triangles are similar. QR QS SR 7 1 3 1 TV U V 14 or 2 and TU 6 or 2 QR QS SR TV U V TU , so by SSS Similarity,

6. Triangles EFD and BCA are right triangles. To determine whether corresponding sides are proportional, find AB. (AB)2 ¬(AC)2 (BC)2 (AB)2 ¬102 52 100 25 AB ¬125 or 55

QRS TVU. E F EG 4 12. F J and IJ IA 5 , but SSA is not a valid justification for similarity. There is not enough information to determine whether the triangles are similar.

EF D E 4 8 and B C 5 AB ¬ 5 5 8 4, so the triangles are not similar because 5 55

13. mR mS mT ¬180 mR 120 20 ¬180 mR ¬40 mJ mK mL ¬180 40 120 mL ¬180 mL ¬20 S K and R J, so RST JKL by AA Similarity.

corresponding sides are not proportional. 7. If the measures of the corresponding sides are proportional, then the triangles are similar. 25 FE D F D E 2 1 9 AB 3 or 3, AC 81 or 3, BC 7 or 3 3 FE D F D E AB AC BC , so by SSS Similarity,

14. ST XV, UT WV, and T V, so STU XVW by SAS Similarity.

DEF ACB.

AB B C 3 1 5 1 15. JK 9 or 3 and KL 15 or 3 , and B K. ABC JKL by SAS Similarity.

8. Triangles ABC and EDF are isosceles triangles because they each have a pair of congruent sides. Base angles of isosceles triangles are congruent, so B C and D F. From the figure, B D, so by transitivity B F and D C. So ABC EDF by AA Similarity. 9. tower

x ft

16. Since A E B D , EAC DBC and AEC BDC because they are corresponding angles. By AA Similarity, AEC BDC. 17. If the measures of the corresponding sides are proportional, then the triangles are similar. 3.5 ST 6 3 SR 10 .5 and B A 2 0 or 10 BC 30 or 10 ST SR , so RST is not similar to CBA B A BC

post

because the sides are not proportional.

4 ft 6 in. 100 ft

18. AE D C , so A C and E D because they are alternate interior angles. By AA Similarity, ABE CBD.

3 ft 4 in.

Assuming that the sun’s rays form similar triangles, the following proportion can be written.

AB EB CB ¬ DB x 3 5 ¬ 2x 8 3

height of tower (ft) tower shadow (ft) height of post (ft) post shadow (ft)

Substitute the known values and let x be the height of the cell phone tower.

3(x 3) ¬5(2x 8) 3x 9 ¬10x 40 7x 9 ¬40 7x ¬49 x ¬7

x ¬ 100 1 1 42 33 x ¬ 41 (100) 31 3 2 1 33 x ¬450

AB x 3 7 3 or 10 BC 2x 8 2(7) 8 or 6

x ¬135 The cellphone tower is 135 feet tall.

Chapter 6

162

19. DC E B , so ADC AEB and ACD ABE because they are corresponding angles. By AA Similarity, ABE ACD.

2 1 2 180 AB 6 2 or 65 2 2 BC 6 3 45 or 35 CA |7 (8)| 15 ST |6 (4)| 10 2 42 TB 8 80 or 45 2 BS 2 42 20 or 25

AE AB AC ¬ AD x 2 8 5 x 2 6 ¬8

8(x 2) ¬(x 8)(3) 8x 16 ¬3x 24 5x 16 ¬24 5x ¬8

6 5 C A 15 AB 3 or 3, and ST 10 or 2 , TB 45 2 BC 3 5 3. or BS 2 25 C A A B BC Since ST TB BS , ABC TBS by SSS

x ¬8 5

AB x 2 3 8 5 2 or 3 5 AC x 2 6 3 8 5 2 6 or 9 5 20. ABD and FEC are right triangles with A F and right angles B and E. Because all right angles are congruent, ABD FEC by AA Similarity.

Similarity. 23. The perimeter of ABC is 65 35 15 or 15 95 . The perimeter of TBS is 45 25 10 or 10 65 . 3(5 35 ) 15 95 or 3 2 2(5 35 ) 10 65

24. False; this is not true for equilateral or isosceles triangles. 25. True; similarity of triangles is transitive. 26. QRS and STR are right angles, so QRS STR. Q Q, so QRS QTR by AA Similarity. S S, so QRS RTS by AA Similarity. Therefore, QTR RTS by transitivity. 27. AB FD, so BAE AFC and ABE ECF because they are alternate interior angles. Then EAB EFC by AA Similarity. A D B C , so ADF ECF because they are corresponding angles. F F, so EFC AFD by AA Similarity. Then EAB AFD by transitivity. 28. PSY and PQR are right angles and so they are congruent. P P, so PSY PQR by AA Similarity. P R W X , so YWX WYP because they are alternate interior angles. WYX YSP because they are right angles, so WYX YSP by AA Similarity.

BD AB CE ¬ FE x 1 3 x 2 ¬ 8

8(x 1) ¬3(x 2) 8x 8 ¬3x 6 5x 8 ¬6 5x ¬14 1 4 x ¬ 5 BD ¬x 1 1 4 9 ¬ 5 1 or 5 EC ¬x 2 1 4 24 ¬ 5 2 or 5 21. ABC and ARS are right triangles with A A and right angles ASR and ACB. Because all right angles are congruent, ABC ARS by AA Similarity. A S SR ¬ AC C B x 6 ¬ 12 9

PY PS ¬ XW X Y P Y 3 1 0 ¬6

9x ¬72 x ¬8 AB ¬x 7 ¬8 7 or 15 AS ¬x ¬8 22.

6(PY) ¬10(3) 6(PY) ¬30 PY ¬5 SY PS ¬ YW X Y SY 3 ¬ 8 6

y

S(0, 6)

C ( 2, 7)

6(SY) ¬8(3) 6(SY) ¬24 SY ¬4

B(4, 4)

PQ PR ¬ PS PY PQ 5 5 3 ¬ 5

x

O

5(PQ) ¬3(10) 5(PQ) ¬30 PQ ¬6 29. PR K L , so RQM LNM, PQM KNM, L QRM, and K QPM, since these are all pairs of corresponding angles. LNM, KNM, RQM, PQM, and LMK are all right angles, so each is congruent to the others.

T (0, 4)

A( 2, 8)

163

Chapter 6

NM 9 8 ¬6

Since LMK MNK and K K, LMK MNK by AA Similarity.

6(NM) ¬8(9)

LK M K M K ¬ NK 16 9 2(KP) KP 2(KP) KP ¬ 9 25 3(KP) 3(K P) ¬9

7 2 NM ¬ 6 or 12

Since L QRM and LNM RQM, QRM NLM by AA Similarity. QR RM ¬ NL LM

25(9) ¬9(KP)2 25 ¬(KP)2 5 ¬KP KM KP PM KP 2(KP) 3(KP) 3(5) or 15 PM 2(KP) 2(5) or 10 Since L QRM and K QPM, LKM RPM by AA Similarity.

3 2

32 4 0 3 (LM) ¬16 3 4 0 3 LM ¬16 3 32

LM ¬20 IJ H J 30. X J YJ and J J,

so IJH XJY by SAS Similarity. mJXY 180 mWXJ 180 130 50 mJIH mJXY by corr. 50 mYIZ mJIH by vert. 50 mJYX mYIZ + mWZG 50 20 70 because exterior angle sum of remote interior angles mJHI mJYX 70 by corr. mJ mJXY mJYX ¬180 mJ 50 70 ¬180 mJ ¬60 mJHG mJHI ¬180 Linear pair mJHG 70 ¬180 mJHG ¬110 31. RST is a right angle, so mRST 90. mRTS 47. mRTS mR mRST ¬180 47 mR 90 ¬180 mR ¬43 UVT is a right angle, so mUVT 90. mUVT mTUV mUTV ¬180 90 mTUV 47 ¬180 mTUV ¬43 RUS is a right angle, so mRUS 90. mRUS mR mRSU ¬180 90 43 mRSU ¬180 mRSU ¬47 SUT is a right angle, so mSUT 90. mSUV mTUV ¬90 mSUV 43 ¬90 mSUV ¬47 32. Assuming that the sun’s rays form similar triangles, the following proportion can be written.

LK KM RP ¬ PM 25 15 R P ¬ 10

25(10) ¬15(RP) 25 0 15 ¬RP 50 3 ¬RP

Since KNM PQM and K QPM, KNM PQM by AA Similarity. KN KM PQ ¬ PM 9 1 5 ¬ PQ 10

9(10) ¬15(PQ) 90 ¬15(PQ) 6 ¬PQ RP RQ PQ 50 3 RQ 6 50 3 6 RQ 32 3 RQ

mMQP mQPM mPMQ ¬180 90 mQPM mPMQ ¬180 mQPM mPMQ ¬90 Since RMP is a right angle, mRMQ mPMQ 90 mQPM mPMQ mRMQ mPMQ mQPM mRMQ, so QPM RMQ. Therefore, RQM MQP by AA Similarity. RQ MQ M Q ¬ QP 32

MQ 3 MQ ¬6 32 (MQ)2 ¬ 3 6

(MQ)2 ¬64 MQ ¬8

QM RM MP ¬ QP RM 8 1 0 ¬6

height of pyramid (ft) height of staff (paces 3)

6(RM) ¬10(8) 80 40 RM ¬ 6 or 3 Since KNM PQM,

pyramid shadow length (paces 3) staff shadow length (paces 3)

NM KN QM ¬ PQ

Chapter 6

4 0

3 3 16 ¬ LM

164

35. Given: L P M N

Substitute the known values and let x be the height of the pyramid.

L J P J Prove: JN JM Proof:

114)(3) (125 x ¬ 2(3) 3(3) x 71 7 ¬ 6 9

9x ¬6(717) 9x ¬4302 x ¬478 The pyramid was about 478 feet tall at that time.

Statements

33. x must equal y. If B D A E , then CBD CAE because they are corresponding angles and C C so BCD ACE by AA Similarity. B C D C 2 x Then AC EC . Thus, 4 x y . Cross multiply and solve for y. 2 ¬x xy 4 2(x y) ¬4x 2x 2y ¬4x 2y ¬2x y ¬x 34. Given: B E; Q P B C ; Q P E F ; AB BC DE EF Prove: ABC DEF A Q

F Reasons 1. Given

AQP B 3. AQP E 4. ABC AQP

Reasons

1. L P M N

1. Given

2. PLN LNM, LPM PMN

2. Alternate Interior Theorem

3. LPJ NMJ

3. AA Similarity

L J P J 4. JN JM

4. Corr. sides of s are proportional. E J H

D

BC BD b. Prove: BE

AB B C P Q E F ; D E EF

2. APQ C

N

A B C Proof: AHB, AJC, and EBC are right angles because perpendicular lines form right angles. Since all right angles are congruent, AHB AJC EBC. Since A A by the Reflexive Property, ABH ACJ, by AA Similarity. Likewise, since C C, ACJ DCB. By the Transitive Property, ABH DCB.

P

1. B E, Q P B C ;

P

J

M

EB A C , B H A E , 36. Given: J C A E a. Prove: ABH DCB

D

B C E Proof: Statements

L

BA

Proof: From part a, A CDB by definition of similar triangles. ABE DBC because all right angles are congruent. Thus, ABE DBC by AA Similarity. BC BD BE BA from definition of similar triangles.

2. Corresponding Postulate 3. Transitive Prop. of 4. AA Similarity

37. Given: BAC and EDF are right triangles. AB AC D E D F Prove: ABC DEF

AB BC 5. AQ Q P

5. Def. of s

6. AB QP AQ BC AB EF DE BC

6. Cross products

7. QP EF

7. Def. of segments

A Proof:

8. AB EF AQ BC

8. Substitution

Statements

9. AQ BC DE BC

9. Substitution

B

E C D

F Reasons

1. BAC and EDF are right triangles.

1. Given

2. BAC and EDF are right angles.

2. Def. of rt.

10. AQ DE

10. Div. Prop.

11. A Q D E

11. Def. of segments

3. BAC EDF

3. All rt. are .

12. AQP DEF

12. SAS

AB AC 4. DE DF

4. Given

13. APQ F

13. CPCTC

5. ABC DEF

5. SAS Similarity

14. C F

14. Transitive Prop.

15. ABC DEF

15. AA Similarity

165

Chapter 6

40. If the side of DEF that is 36 cm corresponds to the shortest side of ABC, then we can find the lengths of the other sides of DEF using proportions.

38. Reflexive Property of Similarity Given: ABC Prove: ABC ABC F C A

D B

3 6 x 4 ¬ 6

E

36(6) ¬4x 216 ¬4x 54 ¬x

I

G

y 3 6 4 ¬ 9

H

Proof: Statements

36(9) ¬4y 324 ¬4y 81 ¬y The perimeter of DEF is 36 54 81 or 171 cm. 41. Assume the lines of sight create similar triangles.

Reasons

1. ABC

1. Given

2. A A, B B

2. Reflexive Prop.

3. ABC ABC

3. AA Similarity

x 87 .6 ¬ 1.92 0.4

Symmetric Property of Similarity Given: ABC DEF Prove: DEF ABC Proof: Statements Reasons 1. ABC DEF

1. Given

2. A D, B E

2. Def. of polygons

3. D A, E B

3. Symmetric Prop.

4. DEF ABC

4. AA Similarity

0.4x ¬1.92(87.6) 0.4x ¬168.192 x ¬420.48 The tower is about 420.5 m tall. 42. It is difficult to measure shadows within a city. 43. Assume that ADFE is a rectangle. D G F

Transitive Property of Similarity Given: ABC DEF and DEF GHI Prove: ABC GHI Proof: Statements

R A A H E Let R be the point on E F where the vertical line from D crosses E F . Then ADR DRF because D A E F and alternate interior angles are congruent. DFR AHG because all right angles are congruent. So AGH DRF by AA Similarity.

Reasons

1. ABC DEF, DEF GHI

1. Given

2. A D, B E, D G, E H

2. Def. of polygons

3. A G, B H

3. Trans. Prop.

4. ABC GHI

4. AA Similarity

GH AH RF ¬ DF x 15 0 ¬0 6 10

10x ¬6(1500) 10x ¬9000 x ¬900 cm or 9 m So, the height of the tree is 9 m 1.75 m or 10.75 m. 44. No; the towns are on different latitudinal lines, so the sun is at a different angle to the two buildings. 45. y

39. MKO MOP because they are both right angles, and M M, so MKO MOP by AA Similarity. OKP is a right angle because it forms a linear pair with right angle MKO. OKP MOP and P P, so MOP OKP by AA Similarity. Then MKO OKP by transitivity. M K O K OK ¬ KP 1. 5 4. 5 4.5 ¬ KP

8

A

1.5(KP) ¬4.5(4.5) 1.5(KP) ¬20.25 KP ¬13.5 The distance KP is 13.5 feet.

B

4

D O

8

C

4 8

Chapter 6

166

4

x

P S SR ¬ AD D C PS 0. 7 2.2 ¬ 1.4

AB BC 46. If ABC ADE then AD DE . Plot point E so that B C D E and the proportion is true.

1.4(PS) ¬2.2(0.7) 1.4(PS) ¬1.54 PS ¬1.1 SR 0. 7 1 The scale factor is CD 1.4 or 2 . 52. Use the congruent angles to write the corresponding vertices in order. EFG XYZ

2 ( AB ¬ [2 (10)] 4 6)2 2 (2) ¬8 2 ¬68 or 217 2 (2 AD ¬ [6 (10)] 6)2 2 ¬16 (4)2 ¬272 or 417

XY Y Z E F ¬ FG 22 .5 7. 5 6x ¬ 10

AB 2 17 or 1 AD 2 , so DE 2(BC). To get 4 17

from point B to point C, move down 6 units and then move left 2 units. To get from point D to point E, move down 12 units and then move left 4 units. Locate point E at (2, 10).

22.5(10) ¬6x(7.5) 225 ¬45x 5 ¬x EF 6x 6(5) or 30

47. ABC ACD by AA Similarity. ABC CBD by AA Similarity. ACD CBD by AA Similarity. 48. Sample answer: Engineers use triangles, some the same shape, but different in size, to complete a project. Answers should include the following. • Engineers use triangles in construction because they are rigid shapes. • With the small ground pressure, the tower does not sink, shift, lean, or fall over.

X Z Y Z ¬ EG FG X Z 7. 5 25 ¬ 10

10(XZ) ¬25(7.5) 10(XZ) ¬187.5 XZ ¬18.75 10 FG 4 The scale factor is YZ 7.5 or 3 . 3 53. 1y ¬ 1 5 15 ¬3y 5 ¬y

AE AB 49. A; ABE ACD by AA Similarity, so AD AC . 4 10 x 2 10 ¬ x 2 5 6 2 ¬ xx 10 3

7 54. 6 8 ¬ b 6b ¬8(7) 6b ¬56 2 8 b ¬ 3

6(x 3) ¬10(x 2) 6x 18 ¬10x 20 18 ¬4x 20 38 ¬4x 9.5 ¬x 50. B; 3 x x 6 ¬ x 2 (x 3)(x 2) ¬6x x2 2x 3x 6 ¬6x x2 x 6 ¬6x 2 x 5x 6 ¬0 (x 6)(x 1) ¬0 x 6 ¬0 or x 1 ¬0 x ¬6 x ¬1

55.

20 m 28 ¬ 21

20(21) ¬28m 420 ¬28m 15 ¬m 1 6 9 56. 7 ¬ s 16s ¬7(9) 16s ¬63 63 s ¬ 16

57. Find the coordinates of T. 12


8

51. Use the congruent angles to write the corresponding vertices in order. PQRS ABCD

4

y

B

x

PQ SR ¬ D C AB x 0 7 ¬. 3.2 1.4

4

4

8

C

12

4

1.4x ¬3.2(0.7) 1.4x ¬2.24 x ¬1.6

8 A

12 AT is a median from A to B C , so T is the midpoint of B C . Then T has coordinates

BC CD Q R ¬ RS B C 1 . 4 0. 7 ¬ 0.7

9 11 (1) 5 2 , 2 (7, 5).

0.7(BC) ¬0.7(1.4) BC ¬1.4

11 1 12 C is The slope of B 9 5 4 or 3.

167

Chapter 6

QR PR ¬ SR TR 5 PT x 10 ¬ x 10 40 15 PT 3 ¬ 10 4 0

5 (9) 14 7 The slope of A T is 7 ( 3) 10 or 5 . 3 7 T is not perpendicular to 5 1, so A

C B . A T is not an altitude.

3

58. p: you are at least 54 inches tall q: you may ride the roller coaster Adam is 5 feet 8 inches tall, or 5 12 8 68 inches, so he can ride the roller coaster by the Law of Detachment. 59.

40 0 60 0 10(PT) 3 ¬ 3 20 0 10(PT) ¬ 3 2 0 PT ¬ 3

9 15 11 2 11 26 2 , 2 ¬2, 2

¬(5.5, 13)

scale on map (cm) distance on map (cm) distance on map (mi) actual distance (mi) 1 .5 29 .2 10 0 ¬x

5.

4 (12) 4 2 2 8 60. 2 ¬ 2, 2 2 , ¬(1, 4)

1.5x ¬100(29.2) 1.5x ¬2920 x ¬1947 The cities are about 1947 miles apart.

7 8 (13) 0 7 5 61. 2 , 2 ¬ 2, 2 ¬(3.5, 2.5)


6-4

1. yes; A E, B D, 1 3, 2 4 and AB BC AF FC ED D C E F FC 1 6.5 6. 5 5 5 2. no; 6 5.5 and 5.5 6 3. D B and AED CEB, so ADE CBE by AA Similarity.

Parallel Lines and Proportional Parts

Pages 311–312


1. Sample answer: If a line intersects two sides of a triangle and separates sides into corresponding segments of proportional lengths, then it is parallel to the third side. 2. Sample answer:

D E AD BE ¬ CB 3x 2 1 0 6 ¬ 15

15(3x 2) ¬6(10) 45x 30 ¬60 45x ¬90 x ¬2

m A

n B D

AE AD ¬ CE CB A E 10 12 ¬ 15

C

15(AE) ¬12(10) 15(AE) ¬120 AE ¬8 DE 3x 2 3(2) 2 or 4

m A

n

B

D C

4. ST Q P , so TSR PQR. R R, so PQR TSR by AA Similarity.

3. Given three or more parallel lines intersecting two transversals, Corollary 6.1 states that the parts of the transversals are proportional. Corollary 6.2 states that if the parts of one transversal are congruent, then the parts of every transversal are congruent.

PQ QR T S ¬ SR 5 25 10 T S ¬ 10

25(10) ¬(10 5)(TS) 250 ¬15(TS) 50 3 ¬TS 2 (SR) (TR)2 ¬(TS)2

4. L W T S , so by the Triangle Proportionality LT W S . Substitute the known Theorem, R L RW measures.

5 0 2 102 x2 ¬ 3 25 00 100 x2 ¬ 9 16 00 x2 ¬9 4 0 x ¬ 3

Chapter 6

4 0 4 0 10 PT 3 ¬ 3 (15)

5 9 6 5 ¬ RW

4(RW) ¬5(6) 4(RW) ¬30 RW ¬7.5

168

5. LW T S , so by the Triangle Proportionality T L W S Theorem, . Substitute the known LR RW measures.

To find y: y ¬3 5y 2 2 y ¬2 5

3 8 WS 3 ¬6

y ¬5

6(5) ¬3(WS) 30 ¬3(WS) 10 ¬WS 6. Use the Midpoint Formula to find the midpoints of A B and A C .

12. To find x: 1x 2 ¬2x 4 3 3 1 3 x 2 ¬4 1 3 x ¬6 x ¬18 To find y:

10 (2) 0 6 D 2, 2 D(4, 3)

4 (2) 0 6 E2, 2 E(3, 3)

5y ¬7 3y 8 8y ¬8 3

7. If the slopes of D E and B C are equal, D E B C .

y ¬3

33 slope of D E 3 4 or 0

13. The streets form a triangle cut by a Walkthrough that is parallel to the bottom of the triangle. Use the Triangle Proportionality Theorem. Talbot Rd. Woodbury Ave.

00 slope of B C 10 (4) or 0

E and B C are equal, Because the slopes of D DE B C . 8. First, use the Distance Formula to find BC and DE. BC ¬ [10 (4)]2 (0 0)2 ¬ 196 0 ¬14 DE ¬ (3 4)2 (3 3)2 ¬ 49 0 ¬7 D E 7 1 BC 14 or 2

Entrance to Walkthrough Entrance to Walkthrough Walkthrough to Clay Rd. Walkthrough to Clay Rd. 8 8 0 x 14 08 ¬ 17 60

880(1760) ¬1408x 1,548,800 ¬1408x 1100 ¬x The distance from the entrance to the Walkthrough along Woodbury Avenue is 1100 yards.

D E 1 1 If BC 2 , then DE 2 BC.

Pages 312–315

9. MQ ¬MR RQ 12.5 ¬4.5 RQ 8 ¬RQ MP ¬MN NP 25 ¬9 NP 16 ¬NP In order to show R N Q P , we must show that

Practice and Apply

14. MN Y Z , so by the Triangle Proportionality M Y N Z Theorem, XM XN . Substitute the known measures. M Y 9 4 ¬ 6 6(MY) ¬4(9) 6(MY) ¬36 MY ¬6 XY XM MY 4 6 or 10

M R M N RQ NP . M R 4.5 9 RQ ¬ 8 or 16 M N 9 NP ¬ 16 M R M N 9 Thus, RQ NP 16 . Since the sides have

15. MN Y Z , so by the Triangle Proportionality M Y N Z Theorem, . Substitute the known XM XN measures. 10 2 t 1 ¬ 2 t2 8(t 2) ¬2(t 1) 8t 16 ¬2t 2 6t 16 ¬2 6t ¬18 t ¬3

N Q P . proportional lengths, R 10. In order to show D B A E , we must show that AB ED DC BC . ED 8 2 DC 20 or 5 AB 12 BC 25 AB E D , so the sides do not have proportional BC DC

16. D E B C , so by the Triangle Proportionality D B EC Theorem, AD AE . Substitute the known measures.

lengths and D B is not parallel to A E .

24 18 ¬ AD 3

11. To find x: 20 5x ¬2x 6 20 ¬7x 6 14 ¬7x 2 ¬x

24(3) ¬18(AD) 72 ¬18(AD) 4 ¬AD

169

Chapter 6

6(x 4) ¬12(8) 6x 24 ¬96 6x ¬120 x ¬20 21. In order to have G J F K , it must be true that

17. E B D C , so by the Triangle Proportionality ED BC Theorem, AE AB . Substitute the known

measures.

2x 3 6 3 ¬2

2(2x 3) ¬3(6) 4x 6 ¬18 4x ¬24 x ¬6 ED 2x 3 2(6) 3 or 9

H G H J GF JK . 4 5 x x 18 ¬ 15

15(x 4) ¬18(x 5) 15x 60 ¬18x 90 3x 60 ¬90 3x ¬30 x ¬10 22. In order to have G J F K , it must be true that

18. BC E D , so by the Triangle Proportionality BE CD Theorem, AB AC . Substitute the known measures. 20 x 5 16 ¬ x 3 20(x 3) ¬16(x 5) 20x 60 ¬16x 80 4x 60 ¬80 4x ¬140 x ¬35 AC x 3 35 3 or 32 CD x 5 35 5 or 40

H G H J GF JK .

(x 3.5)(15.5 x) ¬(17.5 x)(x 8.5) 15.5x x2 54.25 3.5x ¬17.5x 148.75 ¬ x2 8.5x 2 x 12x 54.25 ¬x2 26x 148.75 12x 54.25 ¬26x 148.75 54.25 ¬14x 148.75 203 ¬14x 14.5 ¬x

19. BF C E and A C D F , so by the Triangle BC FE Proportionality Theorem, AB AF and A F C D FE DE . Substitute the known measures.

23. In order to show Q T R S , we must show that PQ PT Q R TS . PQ 9 Q R ¬ 30 9 9 3 ¬ or 21 7 12 PT ¬ 18 12 TS 12 ¬ 6 or 2 PQ PT T is not parallel to R S . Because Q R TS , Q

1 0 3

x x 6 ¬ 8

10 8x ¬6 x 3 8x ¬6x 20 2x ¬20 x ¬10

y 8 ¬ 2y 3 1 0 x 3 y 8 ¬ 2y 3 10 10 3 y 8 ¬ 2y 3 4 0

24. In order to show Q T R S , we must show that PQ PT Q R TS . PQ 22 65 Q R ¬ 22 43 ¬ 22

3

40 8(2y 3) ¬ 3 y

40 16y 24 ¬ 3 y 24 ¬8 3y 9 ¬y BC x 10 10 FE ¬x 3

Let TS x. Then SP 3x and PT 3x x or 2x. x PT 2 TS x 2 PQ PT T is not parallel to R S . Because Q R TS , Q

25. In order to show Q T R S , we must show that PQ PT Q R TS .

10 1 ¬10 3 or 13 3

Let RQ x. Then PQ 2x.

CD y 9 DE 2y 3 2(9) 3 or 15 20. In order to have G J F K , it must be true that H G H J . GF JK

x

PQ 2 1 Q R ¬ x or 2 8.6 PT 12.9 TS ¬ 8.6 4. 3 1 ¬ 8.6 or 2 PQ PT 1 Thus, Q R TS 2 . Since the sides have

6 8 ¬ x 4 12

Chapter 6

x 3.5 x 8.5 21 (x 3.5) ¬ 7 (x 8.5) 3.5 8.5 x x ¬ 17.5 x 15.5 x

T R S . proportional lengths, Q

170

26. In order to show Q T R S , we must show that

30. Use the Distance Formula to find DE and AB.

PQ PT Q R TS . PQ 34. 88 43 6 Q R ¬ 18.32 or 229 11.45 PT 33.25 TS ¬ 11.45 21 .8 43 6 ¬ 11.4 5 or 229 PQ PT 43 6 Thus, Q R TS 229 . Since the sides have

y

A

8 4 x

8

B

T R S . proportional lengths, Q

4

4 4

C

8

27. DE is a midsegment of ABC and D E B C , so by the Triangle Midsegment Theorem, DE 1 2 BC. Then BC 2DE. 2 (3 DE ¬ (4 1) 1)2 ¬ 94 ¬13 BC ¬2DE ¬213 ¬ 4 13 or 52

8

1 32 3 4 2 2

DE ¬

2

81 ¬ 9 4 4 ¬3 2 10 2 ( AB ¬ [4 (1)] 3 6)2 ¬ 9 81 ¬310 10 So, 3 1 ) and thus DE 1 2 2 (310 2 AB.

28. If the slopes of W M and T S are equal, W M T S . 12 14 slope of WM 5 3 or 1

20 26 slope of TS 17 11 or 1 Because the slopes of W M and T S are equal, M W T S . M W is a midsegment of RST if W is the midpoint of R T and M is the midpoint of RS.

31.

y

C

A (2, 12)

11 8 26 1 T is The midpoint of R 2, 2 (5, 17).

These are not the coordinates of W. 17 8 20 1 S is The midpoint of R 2, 2 (8, 14).

D

These are not the coordinates of M. M W is not a midsegment because W and M are not midpoints of their respective sides.

y

8 4 x

8

4

4

B

8

4

C

8

x

Graph AB. We can find segments of AB with lengths in a ratio of 2 to 1 by considering a second line and parallel lines that intersect this line and . AB Graph C(0, 12) and D(0, 0) and lines CA and DB. CA and DB are horizontal lines and are parallel (the y-axis) and lines intersecting transversals CD . We can find P by finding a third parallel line AB intersecting CD and AB so that this line separates CD into two parts with a ratio of 2 to 1. CD is 12 units, so if a horizontal line intersects at (0, 4) or (0, 8) then this line separates CD CD into two parts with a ratio of 2 to 1. These horizontal lines intersect AB at (4, 4) and (3, 8). into parts with a ratio of These points cut off AB 2 to 1, so P could have coordinates (4, 4) or (3, 8).

29. DE is a midsegment of ABC. Use the Midpoint Formula to find the coordinates of D and E.

A

B (5, 0)

6 (5) 1 7 1 D 2 D 3, 2 2 ,

3 (5) 4 7 3 E 2 E2, 4 2 , Find the slopes of D E and A B . 1

4

2 or 3 slope of D E 3

3 36 slope of A B 4 (1) or 3 2

E and A B have slope 3, so D E is parallel Both D to A B .

171

Chapter 6

32.

To find y: 2y 6 ¬3y 9 6 ¬y 9 15 ¬y 34. To find x: 2x 3 ¬6 x 3x 3 ¬6 3x ¬3 x ¬1 To find y: 4y 1 ¬2y 3 1 ¬2 3y 3 ¬y 2

N

y

P

R x

35. The poles form parallel line segments and the wires are transversals cutting through the ends of the parallel segments.

L is on PN and M is on RN so graph N, P, and R and extend P N and R N so that P R divides N L

D

L P 2 and M N . R divides N L and M N PN 1 , and P

M R 2 proportionally so RN 1 . Then LP 2(PN) and MR 2(RN). Starting at N(8, 20), move to P(11, 16) by moving down 4 units and then right 3 units. Locate L by moving from P down 8 units and then right 6 units. The coordinates of L are (17, 8). Now starting at N(8, 20), move to R(3, 8) by moving down 12 units and then left 5 units. Locate M by moving from R down 24 units and then left 10 units. The coordinates of M are (7, 16). Verify that LP 2(PN) and MR 2(RN). PN ¬ (11 8)2 (16 20)2 ¬ 9 16 ¬25 or 5

A 50 ft

C 30 ft

a ft F B

x a 4 0 ¬ 3 0

30x ¬40a

2 (2 RN (8 3) 0 8)2 25 144 169 or 13

30 40 x ¬a 40 x a ¬ 50 40

MR [3 ( 7)]2 [8 (16)] 2 100 576 676 or 26 So, MR 2(RN).

40a ¬50(40 x)

30x ¬2000 50x 80x ¬2000 x ¬25 So, the distance from C to the taller pole is 25 feet. 36.

x 0 a ¬ 4 30

30x ¬40a 30(25) ¬40a 750 ¬40a 18.75 ¬a The coupling is 18.75 feet above the ground.

length is labeled 5 3 x 11. 1 5 x 2 ¬2 3x 11

11 1x 2 ¬ 6 2 1x ¬7 6 2

x ¬21

Chapter 6

30 40 40 x ¬2000 50x

33. To find x: The sides of the large triangle are cut in equal parts by the segment whose length is labeled x 2, so this segment is a midsegment and its length is half the length of the segment whose

E

CFE is a right angle, so CFE ABE and CFB DEB. Also, CEF AEB, so AEB CEF by AA Similarity. CBF DBE, so CBF DBE by AA Similarity.

LP ¬ (11 17)2 (16 8)2 36 64 100 or 10 So, LP 2(PN).

11 x 2 ¬5 6x 2

x ft 40 ft

172

39. Given: D is the midpoint of A B . E is the midpoint of A C . Prove: D E B C ; DE 1 2 BC A E D B C

37. Let y represent the length of the wire from the smaller pole. 302 402 ¬y2 900 1600 ¬y2 2500 ¬y2 50 ¬y Let z represent the length of the wire from the top of the smaller pole to the coupling.

Proof: Statements

25 40 z ¬ 50 z 25

25z ¬15(50 z) 25z ¬750 15z 40z ¬750 z ¬18.75 The coupling is 18.75 feet down the wire from the top of the smaller pole. D B EC 38. Given: AD AE Prove: D E B C

A D

E

B

C

Proof: Statements

Reasons

D B EC 1. AD AE

1. Given

AD D B AE EC 2. AD AD AE AE

2. Addition Prop.

DB EC AD AE 3. AD AE

3. Substitution

4. AB AD DB, AC AE EC AB AC 5. AD AE


6. A A

6. Reflexive Prop.

7. ADE ABC

7. SAS Similarity

8. ADE ABC

8. Def. of polygons

9. D E B C

9. If corr. are , then the lines are .

5. Substitution

Reasons

1. D is the midpoint of A B . E is the midpoint of A C . 2. A D D B , A E E C

1. Given

3. AD DB, AE EC

3. Def. of segments

4. AB AD DB, AC AE EC


5. AB AD AD, AC AE AE

5. Substitution

6. AB 2AD, AC 2AE

6. Substitution

AB AC 2, 2 7. AD AE

7. Division Prop.

AB AC 8. AD AE

8. Transitive Prop.

9. A A

9. Reflexive Prop.

2. Midpoint Theorem

10. ADE ABC

10. SAS Similarity

11. ADE ABC

11. Def. of polygons

12. D E B C

12. If corr. are , then the lines are parallel.

BC AB 13. DE AD


BC 14. D E 2


15. 2DE BC

15. Mult. Prop.

16. DE 1 2 BC

16. Division Prop.

40. Figure is not shown actual size. A

173

B

41. A

B

42. A

B

C

C

D

D

E

C

Chapter 6

a b 47. 2 ¬18 a b ¬36 a ¬36 b

43. The total length of the lots along Lake Creek Drive is 20 22 25 18 28 or 113 meters. The lines dividing the lots are perpendicular to Lake Creek Drive, so they are all parallel. Write proportions to solve for each variable.

a ¬5 b 4 36 b b ¬5 4

total lake frontage total length of lots along street

4(36 b) ¬5b 144 4b ¬5b 144 ¬9b 16 ¬b a 36 b 36 16 or 20 a b 20 16 or 4 48a. See students’ work. E F G H , F G E H , E F G H , G F E H 48b. No, there will be an odd number of sides so it is not possible to pair opposite sides.

individual lake frontage individual length along street 135 .6 u 113 ¬ 20

135.6(20) ¬113u 2712 ¬113u 24 ¬u 135 .6 w 113 ¬ 22

135.6(22) ¬113w 2983.2 ¬113w 26.4 ¬w 135 .6 x 113 ¬ 25

Page 315

135.6(25) ¬113x 3390 ¬113x 30 ¬x

12 9 3 50. Yes, by SSS Similarity; 6 8 12 16 4 51. No; corresponding angles are not congruent. The third angles have measure 180 (72 66) 42 and 180 (66 38) 76.

y 135 .6 113 ¬ 18

135.6(18) ¬113y 2440.8 ¬113y 21.6 ¬y

7 x 52. 2 0 ¬ 1 4

135 .6 z 113 ¬ 28

14x ¬20(7) 14x ¬140 x ¬10

135.6(28) ¬113z 3796.8 ¬113z 33.6 ¬z

y 1 4 9 ¬ 7

44. Use the Triangle Proportionality Theorem in DCA. AB D G D G D E G B A D , so BC GC . Also, in DCF, GC EF . Using the Transitive Property of Equality,

7y ¬126 y ¬18 x 14 53. 1 8 ¬ 21

21x ¬252 x ¬12

AB D E BC EF .

D A

y 14 9 ¬ 21

F

E

21y ¬126 y ¬6 54. If one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. In ADB, ADB is opposite a side whose measure is 15, and ABD is opposite a side whose measure is 12. 15 12, so mADB mABD. 55. If one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. In ADB, ABD is opposite a side whose measure is 12, and BAD is opposite a side whose measure is 9. 12 9, so mABD mBAD.

G B

C

45. Sample answer: City planners use maps in their work. Answers should include the following. • City planners need to know geometry facts when developing zoning laws. • A city planner would need to know that the shortest distance between two parallel lines is the perpendicular distance. 12 x 46. B; 18 ¬ 42 x 12(42 x) ¬18x 504 12x ¬18x 504 ¬30x 16.8 ¬x

Chapter 6


49. Yes, by AA Similarity; the parallel lines determine congruent corresponding angles.

174

4. Let x represent the perimeter of WZX.

56. If one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. In BDC, BCD is opposite a side whose measure is 9, and CDB is opposite a side whose measure is 13. 9 13, so mBCD mCDB. 57. If one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. In BDC, CBD is opposite a side whose measure is 10, and BCD is opposite a side whose measure is 9. 10 9, so mCBD mBCD. 58. There are 6 equilateral triangles. 59. There are 18 obtuse triangles in the figure, 3 in each equilateral triangle. 60. True; the hypothesis is false, so we cannot say that the statement is false. 61. False; the hypothesis is true, but the conclusion is false. 62. True; the hypothesis is false, so we cannot say that the statement is false. 63. True; the hypothesis is true and the conclusion is true. 64. A D, B E, C F, A B D E , C B E F , A C D F 65. R X, S Y, T Z, R S X Y , T S Y Z , R T X Z 66. P K, Q L, R M, P Q K L , R Q L M , P R K M

perimeter of WZX W X ST ¬ perimeter of SRT x 5 ¬ 1 5 6

75 ¬6x 12.5 ¬x The perimeter of WZX is 12.5 units. x 6. 5 5. 1 2 ¬ 13

13x ¬78 x ¬6 20 16 6. x ¬ 12 240 ¬16x 15 ¬x

7.

24x ¬162 x ¬6.75 AB m 8. Given: ABC DEF and D E n perimeter of ABC m Prove: n perimeter of DEF

B A

Page 319

E

C

D F AB AC B C Proof: Because ABC DEF, D E EF DF . AC B C m So EF DF n . Cross products yield m m AB DE m n , BC EF n , and AC DF n .

Using substitution, the perimeter of

Parts of Similar Triangles

6-5

x 8 9 ¬ 1 24

m m ABC DE m n EF n DF n , or m(DE EF DF). The ratio of the two n


perimeters

m(DE EF DF) n

1. ABC MNQ and A D and M R are altitudes, angle bisectors, or medians. 2. Sample answer: The perimeters are in the same 24 2 proportion as the side measures, which is 36 or 3 . So if the smaller triangle has side lengths 6, 8, and 10 (so that its perimeter is 6 8 10 24), then the larger triangle has side lengths 3 (6), 3(8), and 3 (10) or 9, 12, and 15. 2 2 2 3. Let x represent the perimeter of DEF. The perimeter of ABC 5 6 7 or 18.

m DE EF DF or n . height of Tamika distance from camera height of image length of camera 16 5 x ¬ 1 0 5

9. ¬ 1650 ¬5x 330 ¬x Tamika should be 330 cm or 3.3 m from the camera.

perimeter of DEF D E AB ¬ perimeter of ABC

Pages 320–322 Practice and Apply 10. Let x represent the perimeter of BCD. The perimeter of FDE 4 5 8 or 17.

x 3 ¬ 1 8 5

54 ¬5x 10.8 ¬x The perimeter of DEF is 10.8 units.

perimeter of BCD CD DE ¬ perimeter of FDE 1 2 x ¬ 1 7 8

204 ¬8x 25.5 ¬x The perimeter of BCD is 25.5 units.

175

Chapter 6

11. Let x represent the perimeter of ADF. The perimeter of BCE 24 12 18 or 54.

18. Let x represent EG. AD AC ¬ EH EG 1 5 1 7 ¬ 7.5 x

perimeter of ADF D F CE ¬ perimeter of BCE 21 x 18 ¬ 54

15x ¬127.5 x ¬8.5 Thus, EG 8.5. 19. Let x represent EH.

1134 ¬18x 63 ¬x The perimeter of ADF is 63 units. 12. Let x represent the perimeter of CBH. The perimeter of FEH 11 6 10 or 27. ADEG is a parallelogram, so A D G E and BCH HFE. so C H corresponds to F H .

BG B C EH EF 4 2 3 x 12 6 3 x 3

perimeter of CBH CH FH ¬ perimeter of FEH

9 6x 3 x 2

7 x 1 0 ¬ 2 7

Thus, EH 3 2.

189 ¬10x 18.9 ¬x The perimeter of CBH is 18.9 units.

20.

13. Let x represent the perimeter of DEF.

7x x2 ¬10 0 ¬x2 7x 10 0 ¬(x 5)(x 2) x 5 ¬0 or x 2 0 x ¬5 x2 We must choose x 5 because otherwise FB 5 and so FB FG, but the hypotenuse must be longer than either leg. Thus, x 5 and FB 2.

perimeter of DEF D F FC ¬ perimeter of CBF x 6 ¬ 2 7 8

162 ¬8x 20.25 ¬x The perimeter of DEF is 20.25 units. 14. Let x represent the perimeter of ABC. The perimeter of CBD 3 4 5 or 12.

DG D C JM JL 6x 2 x 4

21.

perimeter of ABC CB D B ¬ perimeter of CBD x 5 ¬ 1 2 3

8 6x x2 6x 8 0 (x 4)(x 2) 0 x40 or x20 x4 x2 We must choose x 2 because otherwise JM 4 and so JM JL, but the hypotenuse must be longer than either leg. Thus, x 2 and DC 4.

60 ¬3x 20 ¬x The perimeter of ABC is 20 units. 15. Let x represent the perimeter of ABC. CBD is a right triangle, so use the Pythagorean Theorem to find BD. (CD)2 (BD)2 (CB)2 122 (BD)2 31.22 144 (BD)2 973.44 (BD)2 829.44 BD 28.8 The perimeter of CBD 31.2 28.8 12 or 72.

x2

22.

12 x 5 32 ¬ 2x 3

24x 36 ¬32x 160 36 ¬8x 160 124 ¬8x 15.5 ¬x

perimeter of ABC AB ¬ CB perimeter of CBD x 8.8 52 31 .2 ¬ 7 2

11 20 x 23. 14 ¬ x 11x ¬280 14x 25x ¬280

33.8(72) ¬31.2x 2433.6 ¬31.2x 78 ¬x The perimeter of ABC is 78 units. 16. The original picture is similar to the enlarged picture, so the dimensions and perimeters are proportional. The perimeter of the original picture is 2(18) 2(24) or 84 cm. The perimeter of the enlarged picture is 0.30(84) 84 or 109.2 cm. The enlarged picture will take approximately 109.2 cm of cord, so 110 cm will be enough. 17. Yes, the perimeters are in the same proportion as 300 1 the sides, 600 or 2 .

Chapter 6

FB FG ¬ SA ST 7 x 5 ¬x 2

x ¬11 1 5

24.

3 x x 6 4

4x 12 6x 12 2x 6x 25.

x 9 8 2x

2x2 72 x2 36 x6 x represents a length, which must be positive. So, x 6.

176

26. TA and W B are medians, so RA AS and UB BV. Then RS 2(RA) and UV 2(UB).

31. Given: ABC RST, A D is a median of ABC. U R is a median of RST.

TA RS W B U V 8 2(3) 3x 6 2(x 2) 8 6 3x 6 2x 4

AD AB Prove: RU RS R A

16x 32 18x 36 32 2x 36 68 2x 34 x UB x 2 34 2 or 36 27. B F bisects ABC, so by the Angle Bisector

C

B

T

U

S

Proof: Statements

AF B A . Let x represent CF. Then Theorem, C F BC AF ¬9 x. x 6 9 x ¬ 7.5

67.5 7.5x ¬6x 67.5 ¬13.5x 5 ¬x Thus, CF 5. C A E D , so BED BFC. FBC EBD, so by AA Similarity, EBD FBC. Let y represent BD. BD ED B C ¬ FC y 9 ¬ 7.5 5

5y ¬67.5 y ¬13.5 Thus, BD 13.5

Reasons

1. ABC RST A D is a median of ABC. U R is a median of RST.

1. Given

2. CD DB; TU US

2. Def. of median

AB CB 3. RS TS 4. CB CD DB; TS TU US

3. Def. of polygons 4. Segment Addition Postulate

AB CD DB 5. RS TU US

5. Substitution

AB DB DB 2(D B) 6. RS US US or 2(US)

6. Substitution

AB D B 7. RS US

7. Substitution

8. B S

8. Def. of polygons

9. ABD RSU

9. SAS Similarity

AD AB 10. RU RS

height of person distance from camera 28. ¬ height of image length of camera x 12 7 1 2 ¬ 15


32. Given: CD bisects ACB. By construction E A C D . AD AC Prove: DB B C

15x ¬1008 x ¬67.2 The person is 67.2 inches or about 5 feet 7 inches tall. 29. xy z2; ACD CBD by AA Similarity. Thus,

E C 3 1 2

AD CD 2 z x BD CD or y z . The cross products yield xy z .

A D B Proof: Statements

30. Given: ABC PQR BD BA Prove: Q S QP

B

D

Q

A

C P R D S Proof: Since ABC PQR, A P. BDA QSP because they are both right angles created by the altitude drawn to the opposite side and all right angles are congruent. Thus ABD PQS BA BD by AA Similarity and QS QP by the definition of similar polygons.

177

Reasons

1. CD bisects ACB. By construction, E A C D .

1. Given

AD EC 2. D B BC

2. Triangle Proportionality Theorem

3. 1 2

3. Definition of Angle Bisector

4. 3 1

4. Alternate Interior Angle Theorem

5. 2 E

5. Corresponding Angle Postulate

6. 3 E

6. Transitive Prop.

7. E C A C 8. EC AC

7. Isosceles Th. 8. Def. of congruent segments

AD AC 9. D B B C

9. Substitution

Chapter 6

33. Given: ABC PQR, B D is an altitude of ABC. Q S is an altitude of PQR.

RU bisects SRT. 36. Given: U V R T

QP QS Prove: BA BD

SV SR Prove: VR R T

S

Q

B

U

V A

C P

D

R

R

S

Proof:

Proof: A P because of the definition of similar polygons. Since B D and Q S are perpendicular to A C and P R , BDA QSP. So, QP

Statements

QS

ABD PQS by AA Similarity and BA BD by definition of similar polygons. 34. Given: C BDA

AC AD Prove: D A BA

C B A

D C

Reasons

1. RU bisects SRT. U V R T

1. Given

2. S S

2. Reflexive Prop.

3. SUV STR

3. Corresponding Postulate

4. SUV STR

4. AA Similarity

SV SR 5. VU RT

5. Def. of s

6. URT VUR

6. Alternate Interior Theorem

7. VRU URT

7. Def. of bisector

8. VUR VRU

8. Transitive Prop.

9. V U V R

9. If 2 of a are , the sides opp. these are .

10. VU VR

10. Def. of segments

SV SR 11. VR R T

11. Substitution

BDA

Given

A

ADB

ACD

AA Similarity

A

Reflexive Prop.

AC — DA

AD — BA

Def. of polygons

35. Given: JF bisects EFG. H E F G , E F H G EK G J Prove: KF JF

J E

T

K

F Proof:

37. Given: RST ABC, W and D are midpoints of S T and C B , respectively. Prove: RWS ADB

H G

Statements

A Reasons

1. JF bisects EFG. H E F G , E F H G

1. Given

2. EFK KFG

7. FJH EKF 8. EKF GJF

2. Def. of bisector 3. Corresponding Postulate 4. Vertical are . 5. Transitive Prop. 6. Alternate Interior Theorem 7. Transitive Prop. 8. AA Similarity

EK G J 9. KF JF

9. Def. of s

3. KFG JKH 4. JKH EKF 5. EFK EKF 6. FJH EFK

R B S

C

T

W

Proof: RST

ABC

Given RS — AB

RS — AB

RS — AB

polygons

2WS — 2BD

WS — BD

Def. of Division

178

B polygons

W and D are midpoints.

TS — CB

Def. of

S Def. of

Substitution

Chapter 6

D

Given

2WS TS 2BD CB Def. of midpoint

RWS

ADB

SAS Similarity

PQ 2x 1 2(7) 1 or 15 46. The line goes through (3, 0) and (0, 3). 0 3 m 0 3 or 1 y mx b y 1x (3) yx3 47. y y1 m(x x1) y (1) 2[x (1)] y 1 2x 2 y 2x 1

38. Sample answer: The geometry occurs inside the camera as the image is formed on the film. Answers should include the following. • lens film

object

• The triangles are similar because the SAS Similarity Theorem holds. The congruent angles are the vertical angles and the corresponding sides are the congruent sides of the isosceles triangles. 39. Let x represent DF. AC AB D F ¬ D E 10 .5 6.5 x ¬ 8

48. 5 12 19 26 33 7

7

7

49. 10 20 40 80 160 2

2

2

2

The numbers are multiplied by 2. The next number will be multiplied by 2. So, it will be 160 2 or 320. The next number will also be multiplied by 2. So, it will be 320 2 or 640. 5 4 9 8 13 50. 0

Page 323 Maintain Your Skills 41. LO LM MO 14 7 MO 7 MO LP LN NP 16 9 NP 7 NP In order to show M N O P , we must show that

5

1

5

1

5

The pattern is to add 5 then subtract 1. The last number was obtained by adding 5, so the next number is obtained by subtracting 1. So, it will be 13 1 or 12. The next number is obtained by adding 5, so it will be 12 5 or 17.

LM LM LN LN 7 9 MO NP . MO 7 or 1. NP 7 . Since LM LN N M O NP , the sides are not proportional and M

Page 323

is not parallel to O P .

Practice Quiz 2

D B EC 1. D E B C , so AD AE .

42. There is not enough information given to determine whether M N is parallel to O P . 43. In order to show M N O P , we must show that

DB 18 12 8

12(DB) 144 DB 12 AB AD DB 8 12 or 20 2. AB AD DB 20 4 DB 16 DB D B EC DE B C , so AD AE .

LM LM LN 1 5 LN 12 M O NP . MO 5 or 3. NP 4 or 3. Thus, LM L N M O NP . Since the sides have proportional

N O P . lengths, M 44. V Z Y X , so Z Y and V X. So, VZW ZW VW XYW. Then XW YW . 6 3x 6 x4 5

16 m 4 4 m2

15x 30 6x 24 9x 30 24 9x 54 x6 VW 3x 6 3(6) 6 or 12 WX x 4 6 4 or 10

16m 32 4m 16 12m 32 16 12m 48 m4 3. XY XV VY 30 9 VY 21 VY XZ XW WZ 18 12 WZ 6 WZ In order to show Y Z V W , we must show that

45. R S Q T , so R PQT and S QTP. So, PT PS

PQ PR

PQT PRS. Then . 10 2x 1 10 2x 1 6 4 10 2x 1 14 2x 7

7

The numbers increase by 7. The next number will increase by 7. So, it will be 33 7 or 40. The next number will also increase by 7. So, it will be 40 7 or 47.

84¬ 6.5x 12.9¬ x 40. B; let x be one of the two numbers that are the same. Then x x 3x 180, so 5x 180 or x 36. So, the numbers are 36, 36, and 108. The answer is B.

XV XW XV XW 1 2 9 3 VY WZ . VY 21 or 7 . WZ 6 or 2. Thus, XV XW Z is VY WZ so the sides are not proportional. Y

20x 70 28x 14 70 8x 14 56 8x 7x

W . not parallel to V

179

Chapter 6

4.

XZ XW WZ 33.25 XW 11.45 21.8 XW In order to show Y Z V W , we must show that

Stage 4:

21 .8 XV XW XV 34. 88 43 6 XW 43 6 VY WZ . VY 18.32 or 229 . WZ 11.45 or 229 . XV XW 43 6 Thus, VY WZ 229 . Since the sides have

proportional lengths, Y Z V W . 5. Let x represent the perimeter of DEF. The perimeter of GFH 2 2.5 4 or 8.5. perimeter of DEF E F ¬ perimeter of GFH FH x 6 ¬ 8.5 4

51 ¬4x 12.75 ¬x 6. Let x represent the perimeter of RUW. The perimeter of STV 12 18 24 or 54.

There are 81 nonshaded triangles at Stage 4. 2. Stage 0: 16 16 16 or 48 units Stage 1: 8 8 8 or 24 units Stage 2: 4 4 4 or 12 units Stage 3: 2 2 2 or 6 units Stage 4: 1 1 1 or 3 units 3. The perimeter will be divided by 2 from stage to stage, getting smaller and smaller and approaching zero. 4. Yes, DFM is equilateral with 2 units on each side. Yes, BCE, GHL, and IJN are equilateral with 1 unit on each side. 5. yes, by AA Similarity because each triangle has all angles of measure 60 6. 3, each sharing a side with the shaded triangle in Stage 1.

perimeter of RUW UW VT perimeter of STV 21 x 18 54

1134 18x 63 x 7.

18 x 10 x ¬ 14

252 14x ¬10x 252 ¬24x 10.5 ¬x 6 4 x x 3

8.

4x 12 6x 12 2x 6x x 10 9. 25 ¬ x 2x2 ¬50 x2 ¬25 x ¬5 Because x represents length, x cannot be negative. So, x 5. 10. Let x represent the longest side of the second garden.

7.

8. Three copies of the Stage 4 Sierpinski triangle combine to form a Stage 5 triangle (just as three copies of a Stage 2 triangle combine to form a Stage 3 triangle). 9. 9 copies: 3 to make a Stage 5 triangle, and 3 copies of the Stage 5 triangle, so a total of 3 3 or 9 Stage 4 triangles

53 .5 25 32.1 ¬ x

53.5x ¬802.5 x ¬15 The longest side of the second garden is 15 feet.

Page 324 Geometry Activity: Sierpinski Triangle 1. Stage 3:

6-6

Fractals and Self-Similarity

Page 328 Check for Understanding 1. Sample answer: irregular shape formed by iteration of self-similar shapes 2. They can accurately calculate thousands of iterations. 3. Sample answer: icebergs, ferns, leaf veins

Chapter 6

180

4. Stage 1: 2, Stage 2: 6, Stage 3: 14, Stage 4: 30

Stage 3

5.

14.

Stage Number of Dots Pattern 1 1 10 2 3 21 3 6 33 4 10 46 The formula is the stage number plus the number of dots in the previous stage: An n An 1. So, in the seventh stage, the number of dots is A7 7 A6, where A6 6 A5 and A5 5 A4 5 10 or 15. Then A6 6 15 or 21 and A7 7 21 or 28. So there are 28 dots. 15. 1, 3, 6, 10, 15…; Each difference is 1 more than the preceding difference. 16. The triangular numbers are the numbers in the diagonal. 17. The result is similar to a Stage 3 Sierpinski triangle.

Stage 4

Stage Number of Branches Pattern 1 2 2(21 1) 2 6 2(22 1) 3 14 2(23 1) 4 30 2(24 1) The formula is twice the difference of 2 to a power that is the stage number and 1: An 2(2n 1).

6. No, the base of the tree or segment of a branch without an end does not contain a replica of the entire tree. 7. 2 ¬1.4142… ¬1.1892… 2

1 1 1 1 0 1 1 1 1 1 1 0 0 0 1 1 1 0 0 1 1 1 0 1 0 1 0 1 1 1 1 1 1 1 1 1

2 1.0905…; the results are getting closer to 1, so the result after 100 repeats approaches 1. 9. Yes, the procedure is repeated over and over again. 10. First, write an equation to find the balance after one year. current balance (current balance interest rate) new balance 4000 (4000 0.011) 4044 4044 (4044 0.011) 4088.48 4088.48 (4088.48 0.011) 4133.45 4133.45 (4133.45 0.011) 4178.92 After compounding interest four times, Jamir will have $4178.92 in the account. 8.

Pages 328–331

18. It is similar to a Stage 1 Sierpinski triangle. 1 1 1 1 2 1 1 0 0 1 1 1 0 1 1 1 2 1 1 2 1 1 1

0

0 2

1 0 2

0

0 1

2 0 1

1

19. All of the numbers in the outside diagonal of Pascal’s triangle are 1, so the sum of 25 1’s is 25. 20. The second diagonal consists of the natural numbers, 1, 2, 3, 4, 5,…, 50. The sum is 1 2 3 4 46 47 48 49 50 50 (1 49) (2 48) (3 47) (24 26) 25 50 24(50) 25 1275

Practice and Apply

11. 9 holes

12. 73 holes

13. Yes, any part contains the same figure as the whole, 9 squares with the middle shaded.

181

Chapter 6

21. Given: ABC is equilateral. CD 1 3 CB and CA CE 1 3 Prove: CED CAB

n

28. P 3 4 3 ; as the stages increase, the perimeter increases and approaches infinity. 29. The original triangle and the new triangles are equilateral and thus, all of the angles are equal to 60. By AA Similarity, the triangles are similar. 30. x 12 3.46410… 1.8612… 1.3642… 1.168…

A

E B

x 3.46410… 1.8612… 1.3642… 1.168… 1.0807…

C

D

The numbers converge to 1.

Proof:

31.

Statements

Reasons

1. ABC is equilateral.

1. Given

x

5

0.2

5

0.2

5

1 x

0.2

5

0.2

5

0.2

The numbers alternate between 0.2 and 5.

CD 1 3 CB 1 CE 3CA

32.

C B C 2. A


3. AC BC

3. Def. of segments

1 4. 1 3 AC 3 CB

4. Mult. Prop.

5. CD CE

5. Substitution

CD CE 6. CB CB

x

0.3

1 x3

0.6694… 0.8747… 0.9563… 0.9852…

0.6694… 0.8747… 0.9563… 0.9852… 0.9950…

The numbers converge to 1. 33.

x

0

1

2

4

16

2x

1

2

4

16

65,536

The numbers approach positive infinity. 34.

6. Division Prop.

CD CE 7. CB CA

7. Substitution

8. C C

8. Reflexive Prop.

9. CED CAB

9. SAS Similarity

x

1

3

7

2x 1

3

7

15

x

5

x5

0

x

2

3

8

1

3

8

63

35.

36.

22.

x2 37.

x

0

5

5 10

4

3(2 x) 6

6

24

24 66

38. Write an equation to find the balance each month.

23. Yes; the smaller and smaller details of the shape have the same geometric characteristics as the original form. 24. Stage 1: 6 Stage 2: 36 25. Stage Number of Segments Pattern 0 1 40 1 4 41 2 16 42 3 64 43 The formula is 4 to the power of the stage number: An 4n. So in Stage 8 there are 48 65,536 segments.

39.

27. Stage 0: 3 units, Stage 1: 3 4 3 or 4 units, Stage 2:

4 4 3 4 3 3 3 3 7 1 9 units

Chapter 6

4 or 5 1 3 units, Stage 3: 3 3

1250 (1250 0.015) 100 ¬1168.75 1168.75 (1168.75 0.015) 100 ¬1086.28 1086.28 (1086.28 0.015) 100 ¬1002.57 The balance after 3 months will be $1,002.57.

length of the segments will approach zero. 3

new balance

1 26. Stage 0: 1 unit, Stage 1: 1 3 unit, Stage 2: 9 unit, 1 Stage 3: 2 7 unit; as the stages increase, the

2

current current interest 100 balance rate payment balance

or

0.200 0.64

0.64 0.9216…

0.201 0.6423… 0.6423… 0.9188…

0.9216… 0.2890…

0.9188… 0.2981…

0.2890… 0.8219…

0.2981… 0.8369…

0.8219… 0.5854…

0.8369… 0.5458…

0.5854… 0.9708…

0.5458… 0.9916…

0.9708… 0.1133…

0.9916… 0.0333…

0.1133… 0.4019…

0.0333… 0.1287…

0.4019… 0.9615…

0.1287… 0.4487…

0.9615… 0.1478…

0.4487… 0.9894…

Yes, the initial value affected the tenth value. 40. A small difference in initial data can have a large effect in later data.

182

41. Sample answer: The leaves in the tree and the branches of the trees are self-similar. These selfsimilar shapes are repeated throughout the painting. 42a. The flower and mountain are computergenerated; the feathers and moss are real. 42b. The fractals exhibit self-similarity and iteration. 43. See students’ work. 44.

Page 331


6 21 3x 48. 14 x 4 21x 84 42x 84 84 21x 84 168 21x 8x x 16 49. 17 20 20x 272 x 13 3 5 x 50. 36 8x

3x2 48 x2 16 x 4 Reject x 4 because x represents length, which is positive. So, x 4. 51.

1 2x 7 x 15

105 2x2 x 0 2x2 x 105 (x 7)(2x 15) 0 x 7 0 or 2x 15 0 x7 2x 15 x 7.5 Reject x 7.5 because x represents length, which is positive. So, x 7.

In Stage 1, the shaded triangle has legs 3 and 4 units. The hypotenuse has length c, where c2 32 42, or c 9 16 or 5. So, the perimeter of the triangle is 3 4 5 or 12 units. In Stage 2, there are three small shaded triangles and the larger shaded triangle from Stage 1. Each of the small shaded triangles has legs 2 and 1.5 units. The hypotenuse has length d, where d2 22 1.52, or d 4 2.25 or 2.5. So, the perimeter of all shaded triangles in Stage 2 is 3(2 1.5 2.5) 12 or 30 units. 45. Sample answer: Fractal geometry can be found in the repeating patterns of nature. Answers should include the following. • Broccoli is an example of fractal geometry because the shape of the florets is repeated throughout; one floret looks the same as the stalk. • Sample answer: Scientists can use fractals to study the human body, rivers, and tributaries, and to model how landscapes change over time. 46. Suppose the 24-inch side of the larger triangle corresponds to the smallest side of the smaller triangle. Let P represent the perimeter of the larger triangle. 24 P 3 368 24(3 6 8) 3P 408 3P 136 P The maximum perimeter is 136 inches. 47. C; Let x be the number of minutes the repair technician worked in excess of 30 minutes. 170 ¬80 2x 90 ¬2x 45 ¬x The repair technician worked 30 45 or 75 minutes.

52.

AK B L JA JB 9 18 (JA) JA 27 9 9 18 (JA) JA 1 8

324 18(JA) 9(JA) 324 27(JA) 12 JA JB AB 53. JL KL 8 1 3 JL 1 0

130 8(JL) 16 1 4 JL

54.

AK B L JA ¬ JB 10 1 4 25 ¬ JB

10(JB) ¬350 JB ¬35 55. If one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. The sides of the triangle in order from least to greatest are 965, 1038, and 1042. So, the angles opposite these sides in the same order are arranged from least to greatest. That order is Miami, Bermuda, and San Juan. 56. P 5s 60 5s 12 s Each side has measure 12 cm.

183

Chapter 6

57. P 2 2w 54 2(2x 1) 2(x 2) 54 4x 2 2x 4 54 6x 6 48 6x 8x x 2 8 2 or 10 2x 1 2(8) 1 or 17 The sides of the polygon have measures 10 feet, 10 feet, 17 feet, and 17 feet. 58. P n 2(n 2) 2n 7 57 n 2n 4 2n 7 57 5n 3 60 5n 12 n n 2 12 2 or 14 2n 7 2(12) 7 or 17 The sides of the polygon have measures 17, 14, 14, and 12 units.

14.

25(4 x) ¬16(3 x) 100 25x ¬48 16x 100 ¬48 41x 52 ¬41x

15.

number of total bases from hits 16. number of total at-bats

17.

Page 332 Vocabulary and Concept Check true false, proportional true false, sides false, iteration false, one-half true true false, parallel to

18.

19.

Pages 332–336 Lesson-by-Lesson Review 10.

20.

x 3 1 2 4

28 11. 7 3 z 7z 3(28) 7z 84 z 12

x(x 3) ¬(x 7.5)(x 2) x2 3x ¬x2 2x 7.5x 15 x2 3x ¬x2 5.5x 15 3x ¬5.5x 15 2.5x ¬15 x ¬6 AB x 2 6 2 or 4 AG x 7.5 6 7.5 or 13.5 AD x 6 4 The scale factor is AG x 7.5 13.5 or 9 .

14 2 x 10 5 ¬

10(x 2) ¬5(14) 10x 20 ¬70 10x ¬50 x ¬5 13.

7 3 y 7 3

3(y 3) 7(7) 3y 9 49 3y 58 58 y 3

Chapter 6

26 3 416 0.632 Rewrite 2 : 7 as 2x : 7x and use those measures as the lengths of the pieces of the board after cutting it. 2x 7x 108 9x 108 x 12 2x 2(12) or 24 7x 7(12) or 84 The two pieces have lengths 24 inches and 84 inches. In similar polygons, corresponding sides are in TU U V 6 or 2. But proportion. VW 9 3 UV 1, so two of the sides are in a 2 : 3 ratio while two others are equal in length. Thus, the triangles are not similar. The figures are rectangles, so all angles are LK 24 LM 30 3 3 congruent. RQ 16 or 2 and PQ 20 or 2 , so the sides are in a 3 : 2 ratio. Opposite sides are congruent, so all sides are in a 3 : 2 ratio. Thus, the figures are similar. ABCD AEFG AD AB AG ¬ AE x x2 x 7.5 ¬ x 2 5 x x 2 x 7.5 ¬ x 3

3(12) 4x 36 4x 9x

12.

52 41 ¬x 12 7 x x ¬ 6 4

4(x 12) ¬6(x 7) 4x 48 ¬6x 42 48 ¬10x 42 6 ¬10x 3 ¬x 5

Chapter 6 Study Guide and Review 1. 2. 3. 4. 5. 6. 7. 8. 9.

4 x 16 3 x ¬ 25

184

21. PT S R , so P R and T S because they are alternate interior angles. PQT SQR because they are vertical angles. Thus, PQT RQS.

27. In order to show that G L H K , we must show IH IK that HG KL . IH IK 2 1 3 1 5 5 H G 14 or 2 , and KL 9 or 3 . Because the side lengths are not proportional, L G H K . 28. IL IK KL 36 28 KL 8 KL In order to show that G L H K , we must show IH IK that . HG KL

PQ TQ RQ SQ 6 x 3 6x 3x

(6 x)(3 x) (6 x)(3) 18 6x 3x x2 18 3x 18 3x x2 18 3x 18 x2 18 x2 0 x0 PQ 6 x 6 0 or 6 QS 3 x 3 0 or 3 TQ 3 3 The scale factor is SQ 3 x 3 0 or 1.

IH IK 35 28 7 7 H G 10 or 2 , and KL 8 or 2 . IH IK L H K . HG KL , so G

29. In order to show that G L H K , we must show IH IK that HG KL . Let KL x. Then IL 3x and IK 3x x or 2x. IK x IH IK IH 2 22 KL x or 2, and HG 11 or 2. KL HG . Thus,

22. Triangles ABC and DFE are isosceles triangles. A D, and BA CA and FD ED so B A C A . Thus, ABC DFE by SAS FD ED Similarity. 23. H I J K , so GHI GJK and GIH GKJ because they are corresponding angles. Thus, GHI GJK by AA Similarity. 24. mL mQ mLMQ ¬180 35 85 mLMQ ¬180 mLMQ ¬60 LMQ NMP, so mNMP 60. mN mP mNMP 180 mN 40 60 180 mN 80 LMQ is not similar to PMN because the angles of the triangles are not congruent. 25. Since A B D E , B E and A D because they are alternate interior angles. By AA Similarity, ABC DEC. Using the definition AC BC of similar polygons, EC DC .

L G H K . 30. In order to show that G L H K , we must show IH IK . Let HI x. Then IG 3x, so that HG KL HG 3x x or 2x. IH IK 1 8 x 1 HG 2x or 2 , and KL 6 or 3. So the sides are

L H K . not proportional and G

31. From the Triangle Proportionality Theorem, BC ED AB AE . Substitute the known measures. ED 4 9 6 4(9) 6(ED) 36 6(ED) 6 ED 32. From the Triangle Proportionality Theorem, BC ED AB AE . Substitute the known measures. 16 12 5 1 2 AE 4 5 1 2 AE

x3 1 11x 2 6

6(x 3) 1(11x 2) 6x 18 11x 2 18 5x 2 20 5x 4x 26. V UST and T T, so by AA Similarity, RVT UST. Using the definition of similar RT V T polygons, UT ST .

4(AE) 12(5) 4(AE) 60 AE 15 33. Since B E C D , ABE ACD and AEB ADC by the corresponding angles postulate. Then ABE ACD by the AA Similarity. Using CD AD the definition of similar polygons, BE AE .

4 2x 3 x 2 x2 4 4 2x x5 x 2 4

Substitute the known measures. CD 84 6 8 CD 12 6 8

4(2x 4) (x 2)(x 5) 8x 16 x2 5x 2x 10 8x 16 x2 7x 10 16 x2 x 10 0 x2 x 6 0 (x 3)(x 2) x 3 0 or x 2 0 x3 x 2 Reject x 2 because otherwise UT x 2 2 2 or 0. So x 3.

8(CD) 6(12) 8(CD) 72 CD 9

185

Chapter 6

34. Since B E C D , ABE ACD and AEB ADC by the corresponding angles postulate. Then ABE ACD by the AA Similarity. Using AC CD the definition of similar polygons, AB BE .

39. Stage 2 is not similar to Stage 1.

Substitute the known measures. 33 BC 32 33 24 24(33 BC) 33(32) 792 24(BC) 1056 24(BC) 264 BC 11 35. Let x represent the perimeter of DEF. The perimeter of ABC 7 6 3 or 16.

40. x3 41.

4

60

4

4

60

215,996

x

4

20

3x 4

8 20

56

x

10

0.1

10

1 x

0.1

10

0.1

43.

6x 144 x 24 The perimeter of DEF is 24 units. 36. Let x represent the perimeter of QRS. The perimeter of QTP 15 16 11 or 42.

2

8

42.

perimeter of ABC C B FE perimeter of DEF 16 6 x 9

x

x x 9 1 0

30

6

9.6

6 9.6 9.96


TQ perimeter of QTP ¬ RQ perimeter of QRS 1 5 42 5 ¬ x

Page 337

15x ¬210 x ¬14 The perimeter of QRS is 14 units. 37. Let x represent the perimeter of CPD. CPD BPA and D A, so CPD BPA by AA Similarity. Similar triangles have corresponding medians proportional to the corresponding sides, so the corresponding medians are also proportional to the perimeters.

1. b 2. a 3. c x 1 4. 1 4 2 2x 14 x7 x 10 8 5. 43 x 2 4x 324 x2 81 x 9

perimeter of BPA BM CN perimeter of CPD 1 3 12 x 3 13

6.

x13 3613 x 36 38. Use the Pythagorean Theorem in PQM to find PM. (PM)2 (QM)2 (PQ)2 (PM)2 122 132 (PM)2 169 144 (PM)2 25 PM 5 Since PQM PRQ,

2 k k2 7 ¬3

3(k 2) ¬7(k 2) 3k 6 ¬7k 14 6 ¬4k 14 20 ¬4k 5 ¬k 7. Using corresponding angles, pentagon DCABE CD 12 pentagon DGIHF. The scale factor is G D 18 or 2 : 3. 8. Using corresponding angles, PQR PST. PQ Q R PS ST 2x 2x 2 2x 2 6 1 5 2 2 x 2 x 1 5 2x 8

PQ PM PR PQ 5 1 3 PR 13

5(PR) 13(13) 5(PR) 169 PR 33.8

15(2x 2) 2x(2x 8) 30x 30 4x2 16x 30 4x2 14x 0 4x2 14x 30 0 2x2 7x 15 0 (x 5)(2x 3) x 5 ¬0 or 2x 3 0 x ¬5 x 3 2 3 Reject x 2, because otherwise QR 2x 3, and length must be positive. So, x 5.

PM QM PQ ¬ RQ 5 1 2 ¬ 13 RQ

5(RQ) ¬13(12) 5(RQ) ¬156 RQ ¬31.2 The perimeter of PQR 13 33.8 31.2 or 78.

QR

2 x 2(5 1 0 ) The scale factor is ST 15 15 15 or 2 : 3.

Chapter 6

186

9. Using corresponding angles, MAD MCB.

17. CMA ACB and A A, so ABC ACM by AA Similarity. (AM)2 62 102 (AM)2 36 100 (AM)2 64 AM 8

AM DM CM BM 25 3 x x 20 12

300 3x2 60x 0 3x2 60x 300 0 x2 20x 100 0 (x 10)(x 10) x 10 0 x 10 10) DM 3 x 3( 30 The scale factor is BM 12 12 12 or 5 : 2.

B C AC CM AM B C 1 0 6 8

8(BC) 60 BC 7.5 B C AB ¬ CM AC 7.5 8 MB 6 ¬ 10

PQ 5 1 10. M L 1 0 or 2 PR 6 1 M N 1 2 or 2 QR 3 or 1 6 2 LN

75 ¬448 6(MB) 27 ¬6(MB) 4.5 ¬MB The perimeter of ABC is 10 7.5 8 4.5 or 30.

Corresponding sides are proportional, so the triangles are similar by SSS Similarity. 11. PTS QTR since they are vertical angles. mPTS mQTR 90. mPTS mS mP 180 90 62 mP 180 mP 28 mQTR mR mQ 180 90 66 mQ 180 mQ 24 Since only one pair of corresponding angles is congruent, the triangles are not similar. 12. E D C B so AED ACB and ADE ABC because corresponding angles are congruent. Then the triangles are similar by AA Similarity. 13.

18.

12

87

5x 27 12

87

462

height of fence

4 ft 20 in. x ¬ 65 in. 48 20 x ¬ 65

3120 ¬20x 156 ¬x The height of the top of the backboard is 156 inches, or 13 feet. Y X 20. B; X Y is spent, which is X as part of the weekly salary.

G K GH KJ HI KJ 8 12 KJ 4


K G GH KJ HI 7 G K 6 14 7 G K 7 6 7

1. B; |8 2| |6| 6 2. B; d [5 (3)]2 (2 17)2 2 (2) (1 5)2 4 225 229 miles

7(GK) 42 GK 6 15.

shadow of fence

19. height of backboard shadow of backboard

4(8 KJ) 12(KJ) 32 4(KJ) 12(KJ) 32 16(KJ) 2 KJ 14.

3

x

G K GH KJ HI 6 9 H I 4

3. A 4. D 1.5 cm 11.25 cm 5. A; 2 ft ¬ x ft 1.5x ¬22.5 x ¬15 ft

6(HI) 36 HI 6 GI GH HI 9 6 or 15 16. Let x represent the perimeter of DEF.

45 5 6. B; 63 7 , so the dimensions could be 7 inches by 5 inches. 7. C; us pr because side UT corresponds to side RQ and side ST corresponds to side PQ. 8. D 9. counterexample

perimeter of ACB CB EF perimeter of DEF 10 7 10 13 x 14 10 30 14 x

10x 420 x 42 The perimeter of DEF is 42 units.

187

Chapter 6

10. y y1 m(x x1) y 2 3(x 2) y 2 3x 6 y 3x 4

13d. The new monthly rate will be $25 per month, so the equation will be y 25x 40. The graph will have a less steep slope. 14a. Using the Triangle Proportionality Theorem, if a line is parallel to one side of a triangle and intersects the other two sides in two distinct points, then it separates these sides into AE AD segments of proportional length, so AC AB . Since the corresponding sides are proportional and the included angle, A, is the same, by SAS Similarity Theorem we know that the triangles are similar. 14b. If B is between A and D and C is between A and AB AD E, then BC DE .

11. PQ 1 2 EF 20 1 2 (3x 4) 20 3 2x 2 18 3 2x 12 x perimeter of model 20 cm 12. 40 m ¬ 23 40 46 20 x 40 ¬ 109

2180 ¬40x 54.5 ¬x The perimeter of the model is 54.5 cm.

350 0 3500 1500 DE 1400 ¬ 350 0 500 0 1400 ¬ DE

40) (160 13a. m (4 0)

3500(DE) ¬7,000,000 DE ¬2000 If D is between A and B and E is between A and AB AD C, then BC D E.

12 0 4 30 13b. The slope represents the monthly flat rate, so the company charges a flat rate of $30 per month. 13c. y y1 m(x x1) y 40 30(x 0) y 40 30x y 30x 40

Chapter 6

350 0 3500 1500 DE 1400 ¬ 350 0 200 0 1400 ¬ DE

3500(DE) ¬2,800,000 DE ¬800 So, DE is 2000 feet or 800 feet.

188

Chapter 7 Right Triangles and Trigonometry Page 341

Getting Started

7-1

12 1. 3 4 ¬ a 3a ¬48 a ¬16 2. 5c ¬8 3 3c ¬40 c ¬13.33 e 6 3. 20 ¬ 5 5e ¬120 e ¬24 6 ¬f 10 5 60 ¬5f 12 ¬f

Page 343 Geometry Software Investigation 1. 2. 3. 4.

1. Sample answer: 2 and 72. Let x represent the geometric mean. 2 ¬x x 72 x2 ¬144 x ¬ 144 or 12 2. C

4 ¬1 z 3

4z ¬3 z ¬0.75

A

D B For leg C B , D B is the segment of the hypotenuse that shares an endpoint. Thus, it is the adjacent segment. The same is true for leg A C and segment D A . 3. Ian; his proportion shows that the altitude is the geometric mean of the two segments of the hypotenuse. 4. Let x represent the geometric mean. 9 x ¬ x 4 2 x ¬36 x ¬ 36 or 6 5. Let x represent the geometric mean.

5. c2 52 122 c2 25 144 169 c 13 6. c2 62 82 c2 36 64 100 c 10 7. c2 152 152 c2 225 225 450 c 21.21 8. c2 142 272 c2 196 729 925 c 30.41 9. 8 42 4 2 2 2

36 x x ¬ 4 9

10. 100 25 75 25 3 25 3 53 2 11. 39 362 1521 129 6 225 15 52

x2 ¬1764 x ¬1764 or 42 6. Let x represent the geometric mean. 6 ¬x x 8 x2 ¬48 x ¬ 48 or 4 3 x ¬6.9 7. Let x represent the geometric mean. 2 ¬x 2

7 72 12. 2

See students’ work. They are equal. They are equal. They are similar.


6 4. 4 3 ¬ y 4y ¬18 y ¬4.5

102

Geometric Mean

2 2

7 2 2 4 13. x 44 38 ¬180 x 82 ¬180 x ¬98 14. x 40 155 x 115 15. x 2x 21 90 ¬180 3x 111 ¬180 3x ¬69 x ¬23 7 2

x

32

x2 ¬12 x ¬12 or 23 x ¬3.5 8. Let x CD. AD CD ¬ CD BD 2 ¬x x 6

x2 ¬12 x ¬12 or 23 x ¬3.5

189

Chapter 7

9. Let x EH.

15. Let x represent the geometric mean. x 45 x ¬ 80

GH EH EH ¬ FH 16 12 x x ¬ 1 2

x2 ¬3600 x2 ¬60

x2 ¬48 x ¬48 or 43 x ¬6.9 BD CD 10. CD ¬ AD x 8 x ¬3

x2 ¬24 x ¬24 x ¬2 6 BD CD 11. CD ¬ DA

x 2 3 ¬ 2 23

2x ¬12

x ¬60 or 215 x ¬7.7 16. Let x represent the geometric mean.

CA B A CA ¬ DA y 8 3 y ¬ 3

28 ¬x x 1372

x2 ¬38,41 6

y2 ¬33 y ¬33

x2 ¬196 x ¬196 or 14 17. Let x represent the geometric mean.

B A B C ¬ BC BD y x 2 y ¬x y 6 2 y ¬6

x ¬6

3

5 x x ¬1 x2 ¬53

y2 ¬48 y ¬48 or 43

12.

x ¬ 3 5 3 x 5

Z

15 x ¬ 5

x ¬0.8 18. Let x represent the geometric mean. 3 8 5

¬x x 3 6 5

14 4 x2 ¬ 25

wall

14 4 x ¬ 25

44 1 2 5 1 2 x ¬ 5 or 2.4

x ¬

Y

X

5 ft

19. Let x represent the geometric mean. 2 2

W

x 6 x ¬ 2 5

Draw a diagram. Let Y X be the altitude drawn from the right angle of WYZ.

20 x2 ¬ 36

12 ft

6

20 x ¬ 36

W X YX YX ¬ ZX 5 1 2 ¬ 12 ZX

0 2 6 3 5 2 x ¬ 6 5 x ¬ 3

x ¬

5ZX ¬144 ZX ¬28.8 Khaliah estimates that the wall is about 5 28.8 or 33.8 feet high.

x ¬0.7 20. Let x represent the geometric mean.


13

7 x x ¬ 5

13. Let x represent the geometric mean. x 5 x ¬6 x2 ¬30 x ¬ 30 x ¬5.5 14. Let x represent the geometric mean. 24 x x ¬ 2 5 2 x ¬600 x ¬ 600 or 106 x ¬24.5 Chapter 7

7

x2

65 ¬ 49

65 x ¬ 49 x ¬ 7

65

49

x ¬1.2

190

65

y x ¬ y 6

21. Let x ¬AD. AD BD ¬ CD AD x 5 x ¬9

y2 6x 5 0 y2 6 3

y2 100 y ¬100 y ¬10

x2 ¬45 x ¬45 or 35 x ¬6.7 22. Let x ¬EH.

z x ¬ x 6 z

FH EH ¬ EH GH x 12 x ¬ 12

z2 x2 6x 2

5 0 5 0 z2 3 6 3 25 00 z2 9 100

x2 ¬144 x ¬144 or 12 23. Let x ¬LM.

16 00 z2 9

1600 4 0 z ¬ 9 or 3

JM LM ¬ LM KM 8 x x ¬ 1 6

29. z2 52 ¬152 z2 25 ¬225 z2 ¬200 z ¬ 200 or 102 z ¬14.1 z 15 z ¬x 15x ¬z2 2 15x ¬(10 2) 15x ¬200

x2 ¬128 x ¬128 or 82 x ¬11.3 24. Let x QS. PS Q S Q S ¬ RS 21 x x ¬7

4 0 x ¬ 3

x2 ¬147 x ¬147 x ¬12.1 25. Let x UW.

1 5 5 5 ¬ y

15y 25 y ¬5 3

VW UW ¬ UW TW 2 x x ¬ 1 3

30. x2 42 ¬102 x2 16 ¬100 x2 ¬84 x ¬ 84 or 221 x ¬9.2

x2 ¬26 x ¬26 x ¬5.1 26. Let x ZN.

y4 10 ¬4 10

ZN YN ZN ¬ XN 2 .5 x x ¬ 1 0

4y 16 ¬100 4y ¬84 y ¬21 zy4 z 21 4 25

x2 ¬25 x ¬25 or 5

3 8 x 27. x ¬8

6x 36 31. 3 6 ¬x

6x2 ¬1296 x2 ¬216 x ¬ 216 or 66 x ¬14.7

x2 ¬88 x ¬88 or 222 x ¬9.4

y 3 8 y ¬3

y 6x x ¬ y x

y2 ¬33 y ¬33 y ¬5.7

y2 ¬7x2 y2 ¬7(66 )2 2 y ¬1512 y ¬ 1512 or 642 y ¬38.9

z 8 z ¬3

z2 ¬24 z ¬24 or 26 z ¬4.9 28.

6x x ¬6z z x

z2 ¬42x2 z2 ¬42(66 )2 2 z ¬9072 z ¬ 9072 or 367 z ¬95.2

8 6 ¬ x 8 6

6x 36 ¬64 6x ¬100 50 x ¬ 3

191

Chapter 7

12 x 32. x ¬8 x2 ¬96 x ¬ 96 or 46 x ¬9.8

40. Sample answer: The golden ratio occurs when the geometric mean is approximately 1.62. 41. Let x be the length of the brace. Let y be the segment of the hypotenuse adjacent to the leg with measure 3 yards.

y 12 8 y ¬8

y2 ¬32 y ¬32 or 42 y ¬5.7 12 z z ¬ 12 8 2 z ¬48 z ¬ 48 or 43 z ¬6.9

5 yd

a 17 33. ¬ b

4 yd

y

x

17

ab ¬17 3 yd

7b ¬17

5 ¬3 y 3

17 b ¬ 7

5y ¬9

x 12 34. ¬ y

y ¬9 5

12

xy ¬12 x3 ¬12

y x ¬ 5 y x

x2 ¬5y y2

12 3

x ¬ or 43 x ¬6.9

81 x2 ¬9 25

35. Never; let x and x 1 be consecutive positive x (x 1) integers. The average of the numbers is 2x 1 or 2

14 4 x2 ¬ 25

2

14 4 1 2 x ¬ 25 or 5 x ¬2.4 The brace is 2.4 yards long.

2x 1 2

x ¬ 2x 1 x1 2 2 4x 1 4x 2 x x ¬ 4 x2 x ¬x2 x 1 4 1 0 ¬4 Since 0 ¬1 4 , the first equation is never true.

36.

37.

38. 39.

42. Let x be the geometric mean. The number of players from Indiana is 10, and the number of players from North Carolina is 7. 10 x x ¬ 7 x2 ¬70 x ¬ 70 x ¬8.4 43. Let x be the geometric mean between UCLA and Clemson.

The average of the numbers is not the geometric mean of the numbers. Always; let a and b be positive integers, and let x be the geometric mean of a2 and b2. 2 a ¬x x b2 a2b2 ¬x2 (ab)2 ¬x2 ab ¬x Because a and b are positive integers, their product x is a positive integer. Sometimes; let a and b be positive integers, and let x be their geometric mean. a ¬x b x ab ¬x2 ab ¬x x is an integer when ab is a perfect square. Sometimes; true when the triangle is a right triangle, but not necessarily true otherwise. FGH is a right triangle. O G is the altitude from the vertex of the right angle to the hypotenuse of that triangle. So, by Theorem 7.2, OG is the geometric mean between OF and OH, and so on.

Chapter 7

2

9 x2 ¬59 5 5

15 x x ¬6

x2 ¬90 x ¬90 x ¬3 10 Let y be the geometric mean between Indiana and Virginia. y 10 y 9 y2 ¬90 y ¬ 90 y ¬3 10 The geometric mean between Indiana and Virginia is the same as for UCLA and Clemson.

192

44.

AD CD ¬ CD BD 1 2 C D ¬4 CD

47. Given: ADC is a right angle. D B is an altitude of ADC.

(CD)2 ¬48

Statements

1. PQR is a right angle. S Q is an altitude of PQR. 2. Q S R P 3. 1 and 2 are right angles. 4. 1 PQR 2 PQR 5. P P R R 6. PSQ PQR PQR QSR 7. PSQ QSR

Q 2 P 1 S

R

AB AD 4. AD AC , BC D C D C AC

Reasons 1. Given

C

1. Given

2. Definition of right triangle 3. If the altitude is drawn from the vertex of the rt. to the hypotenuse of a rt. , then the 2 s formed are similar to the given and to each other. 4. Definition of similar polygons

48. Sample answer: The geometric mean can be used to help determine the optimum viewing distance. Answers should include the following. • If you are too far from a painting, you may not be able to see fine details. If you are too close, you may not be able to see the entire painting. • A curator can use the geometric mean to help determine how far from the painting the roping should be. 6 49. C; 6x ¬ 10 10x ¬36 x ¬3.6

2. Definition of altitude 3. Definition of perpendicular lines 4. All right are . 5. Congruence of angles is reflexive. 6. AA Similarity (statements 4 and 5) 7. Similarity of triangles is transitive.

46. Given: ADC is a right angle. D B is an altitude of ADC.

B

Reasons

1. ADC is a right angle. D B is an altitude of ADC. 2. ADC is a right triangle. 3. ABD ADC DBC ADC

12 4 8 ¬ D E 43

Statements

A

A B AD Prove: AD AC , BC D C D C AC Proof:

CD ¬48 or 43 (CB)2 (CD)2 (DB)2 (CB)2 (43 )2 42 2 (CB) 48 16 (CB)2 64 CB 64 or 8 AB CB CED ACB, so CD D E. 16DE ¬323 DE ¬23 45. Given: PQR is a ≈ right angle. Q S is an altitude of PQR. Prove: PSQ PQR PQR QSR PSQ QSR Proof:

D

y 8 ¬ 10 8

10y ¬64 y ¬6.4 50. B; 5x2 405 ¬1125 5x2 ¬720 x2 ¬144 x ¬144 x ¬12

D

A C AB D B Prove: B D B CB Proof: It is given that ADC is a right angle and B D is an altitude of ADC. ADC is a right triangle by the definition of a right triangle. Therefore, ADB DCB, because if the altitude is drawn from the vertex of the right angle to the hypotenuse of a right triangle, then the two triangles formed are similar to the given AB D B triangle and to each other. So D B CB by definition of similar polygons.


x

12

15

18

x3

15

18

21

x

4

14

44

3x 2

14

44

134

x

3

7

47

2

7

47

2207

52.

53. x2 54.

193

x

1

4

14

2(x 3)

4

14

34 Chapter 7

66. c2 32 52 c2 9 25 c2 34 c 34 c 5.8 The length of the hypotenuse is about 5.8 inches.

55. The smallest angle is opposite the side with the smallest measure, 20. Let x and 20 x be the measures of the segments formed by the angle bisector. By the Angle Bisector Theorem, 24 x ¬ 20 x 30 . x 2 4 ¬ 20 x 30

30x ¬480 24x 54x ¬480

Page 349 Geometry Activity: The Pythagorean Theorem

8 0 8 x ¬ 9 or 8 9 10 0 1 20 x ¬ 9 or 11 9

56.

57.

58.

59.

60.

1. yes 2. a2 b2 c2 3. Sample answer: The sum of the areas of the two smaller squares is equal to the area of the largest square.

1 The segments have measures 8 8 9 and 11 9 . By the Exterior Angle Inequality Theorem, m8 m6, m8 m3 m4, and m8 m2. Thus, the measures of 6, 4, 2, and 3 are all less than m8. By the Exterior Angle Inequality Theorem, m1 m5 and m1 m7. Thus, the measures of 5 and 7 are greater than m1. By the Exterior Angle Inequality Theorem, m1 m7 and m6 m7. Thus, the measures of 1 and 6 are less than m7. By the Exterior Angle Inequality Theorem, m2 m6, m7 m6, and m8 m6. Thus, the measures of 2, 7, and 8 are all greater than m6. y mx b y 2x 4

7-2

Pages 353–354 Check for Understanding 1. Maria; Colin does not have the longest side as the value of c. 2. Since the numbers in a Pythagorean triple satisfy the equation a2 b2 c2, they represent the sides of a right triangle by the converse of the Pythagorean Theorem. 3. A

0 8 61. m 02 8 2 or 4

3 5

3

C

D

y mx b y 4x (8) y 4x 8

F

6 3 or 2

6

B

6 5

6

06 62. m 1 2

E

12

Sample answer: ABC DEF, A D, B E, and C F, A B corresponds to D E , C B corresponds to E F , A C corresponds to D F . The scale factor is 2 1 . No; the measures of the sides do not form a Pythagorean triple since 6 5 and 3 5 are not whole numbers. 4. x2 62 ¬102 x2 36 ¬100 x2 ¬64 x ¬ 64 or 8

y y1 ¬m(x x1) y 6 ¬2(x 2) y 6 ¬2x 4 y ¬2x 2 63. y y1 ¬m(x x1) y (3) ¬4[x (2)] y 3 ¬4(x 2) y 3 ¬4x 8 y ¬4x 11 64. c2 ¬32 42 c2 ¬9 16 c2 ¬25 c ¬ 25 or 5 The length of the hypotenuse is 5 cm. 65. c2 52 122 c2 25 144 c2 169 c 169 or 13 The length of hypotenuse is 13 feet.

Chapter 7

The Pythagorean Theorem and Its Converse

2

2

5 5. x2 4 7 ¬ 7 16 25 x2 49 ¬ 49 9 x2 ¬ 49

9 3 x ¬ 49 or 7 6. 202 37.52 ¬x2 400 1406.25 ¬x2 1806.25 ¬x2 1806. 25 ¬x 42.5 ¬x

194

7.


y

K (1 , 6 )

12. The altitude divides the side of measure 14 into two congruent segments of measure 7 because the triangle is an isosceles triangle. x2 72 ¬82 x2 49 ¬64 x2 ¬15 x ¬ 15 x ¬3.9 13. x2 42 ¬82 x2 16 ¬64 x2 ¬48 x ¬ 48 or 4 3 x ¬6.9 14. 202 282 ¬x2 400 784 ¬x2 1184 ¬x2 1184 ¬x 4 74 ¬x 34.4 ¬x 15. 402 322 ¬x2 1600 1024 ¬x2 2624 ¬x2 2624 ¬x 8 41 ¬x 51.2 ¬x 16. x2 252 ¬332 x2 625 ¬1089 x2 ¬464 x ¬ 464 x ¬4 29 x ¬21.5 17. x2 152 ¬252 x2 225 ¬625 x2 ¬400 x ¬ 400 or 20 18. y

L(3, 5) J (2 , 2 ) O

x

2 (6 JK [1 (2)] 2)2 12 42 or 17 2 KL [3 (1)] (5 6)2 2 2 4 ( 1) or 17 2 JL [3 (2)] (5 2)2 52 32 or 34 JK 2 KL2 ¬JL2 2

17

2

2

17 ¬34 17 17 ¬34 34 ¬34 Yes; JKL is a right triangle since the sum of the squares of two sides equals the square of the longest side. 8. Since the measure of the longest side is 39, 39 must be c, and a or b are 15 and 36. a2 b2 ¬c2 152 362 ¬392 225 1296 ¬1521 1521 ¬1521 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple. 9. Since the measure of the longest side is 21, 21 must be c, and a or b are 40 and 20. a2 b2 ¬c2 2

40

202 ¬212 40 400 ¬441 440 ¬441

R(1, 6)

Since 400 441, segments with these measures cannot form a right triangle. Therefore, they do not form a Pythagorean triple. 10. Since the measure of the longest side is 108, 108 must be c, and a or b are 44 and 8. a2 b2 ¬c2 2 2 44 82 ¬ 108 44 64 ¬108 108 ¬108 Since 108 108, segments with these measures form a right triangle. However the three numbers are not all whole numbers. Therefore, they do not form a Pythagorean triple. 11. Let x represent the width of the screen. 11.52 x2 ¬192 132.25 x2 ¬361 x2 ¬228.75 x ¬ 228.7 5 x ¬15.1 The screen is about 15.1 inches wide.

S(9, 0)

O

Q(1, 0)

x

2 (6 QR (1 1) 0)2 02 62 36 or 6 2 (0 RS (9 1) 6)2 82 ( 6)2 100 or 10 2 (0 QS (9 1) 0)2 2 2 8 0 64 or 8 QR2 QS2 ¬RS2 62 82 ¬102 36 64 ¬100 100 ¬100 Since the sum of the squares of two sides equals the square of the longest side, QRS is a right triangle.

195

Chapter 7

RS [6 (4)]2 [ 9 ( 4)]2 2 2 (2) (5) or 29

19. y R (0, 6)

S (6, 6)

Q (3, 2) x 2 (6 QR (0 3) 2)2 (3)2 42 25 or 5

22.

2 (6 RS (6 0) 6)2 2 2 6 0 36 or 6 2 (6 QS (6 3) 2)2 32 42 25 or 5 2 QR QS2 ¬RS2 52 52 ¬62 25 25 ¬36 50 ¬36 Since the sum of the squares of two sides is not equal to the square of the longest side, QRS is not a right triangle.

20.

23.

y

R (2, 11) Q ( 4, 6)

24. x S (4, 1) 2 QR [2 (4)] (11 6)2 2 2 6 5 or 61 2 ( RS (4 2) 1 11)2 2 2 2 ( 12) or 148 2 QS [4 (4)] (1 6)2 2 2 8 ( 7) or 113 QR2 QS2 ¬RS2 2

61

2

25.

2

113 ¬148

61 113 ¬148 174 ¬148 Since the sum of the squares of two sides is not equal to the square of the longest side, QRS is not a right triangle. 21.

y

Q (9, 2)

x

R (4, 4)

S (6, 9)

QR [4 (9)]2 [ 4 ( 2)]2 2 2 5 ( 2) or 29

Chapter 7

196

QS [6 (9)]2 [ 9 ( 2)]2 2 2 3 ( 7) or 58 QR2 RS2 ¬QS2 2 2 2 ( 29) ( 29) ¬( 58) 29 29 ¬58 58 ¬58 Since the sum of the squares of two sides equals the square of the longest side, QRS is a right triangle. Since the measure of the longest side is 17, 17 must be c, and a or b are 8 and 15. a2 b2 ¬c2 82 152 ¬172 64 225 ¬289 289 ¬289 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple. Since the measure of the longest side is 25, 25 must be c, and a or b are 7 and 24. a2 b2 ¬c2 72 242 ¬252 49 576 ¬625 625 ¬625 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple. Since the measure of the longest side is 31, 31 must be c, and a or b are 20 and 21. a2 b2 ¬c2 2 20 212 ¬312 400 441 ¬961 841 ¬961 Since 841 961, segments with these measures cannot form a right triangle. Therefore, they do not form a Pythagorean triple. Since the measure of the longest side is 37, 37 must be c, and a or b are 12 and 34. a2 b2 ¬c2 122 342 ¬372 144 1156 ¬1369 1300 ¬1369 Since 1300 1369, segments with these measures cannot form a right triangle. Therefore, they do not form a Pythagorean triple.

7 4 26. Since the measure of the longest side is , 35 7 4 1 1 must be c, and a or b are and . 35 5 7

a2 b2 ¬c2

1 5

33. Sample answer: They consist of any number of similar triangles. 34. Yes; the measures of the sides are always multiples of 5, 12, and 13. 35a. Find multiples of the triple 8, 15, 17. 8 2 ¬16 15 2 ¬30 17 2 ¬34 162 302 ¬342 256 900 ¬1156 1156 ¬1156 8 3 ¬24 15 3 ¬45 17 3 ¬51 242 452 ¬512 576 2025 ¬2601 2601 ¬2601 Two triples are 16-30-34 and 24-45-51. b. Find multiples of the triple 9, 40, 41. 9 2 ¬18 40 2 ¬80 41 2 ¬82 182 802 ¬822 324 6400 ¬6724 6724 ¬6724 9 3 ¬27 40 3 ¬120 41 3 ¬123 272 1202 ¬1232 729 14,400 ¬15,129 15,129 ¬15,129 Two triples are 18-80-82 and 27-120-123. c. Find multiples of the triple 7, 24, 25. 7 2 ¬14 24 2 ¬48 25 2 ¬50 142 482 ¬502 196 2304 ¬2500 2500 ¬2500 7 3 ¬21 24 3 ¬72 25 3 ¬75 212 722 ¬752 441 5184 ¬5625 5625 ¬5625 Two triples are 14-48-50 and 21-72-75. 36. d (105 122)2 (40 38)2 2 22 (17) 289 4 293 17.1 The distance from San Francisco to Denver is about 17.1 degrees. 37. d (105 115)2 (40 36)2 2 2 (10) 4 100 16 116 10.8 The distance from Las Vegas to Denver is about 10.8 degrees.

4 7 1 7 ¬ 35

2

2

2

1 1 74 25 4 9 ¬ 1225 7 4 7 4 ¬ 1225 1225

These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. However, the three numbers are not whole numbers. Therefore, they do not form a Pythagorean triple. 35 27. Since the measure of the longest side is 36 , 35 3 2 36 must be c, and a or b are 2 and 3 .

a2 b2 ¬c2

2 32 ¬3356 3

2

2

2

122 5 3 2 ¬ 4 9 1296 35 122 5 36 ¬ 1296 35 122 5 Since 36 1296 , segments with these measures

cannot form a right triangle. Therefore, they do not form a Pythagorean triple. 28. Since the measure of the longest side is 1, 1 4 must be c, and a or b are 3 5 and 5 . 2 2 2 a b ¬c 3

2

5

2

2 4 5 ¬1

9 16 25 25 ¬1 25 25 ¬1

These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. However, the three numbers are not all whole numbers. Therefore, they do not form a Pythagorean triple. 10 1 0 29. Since the measure of the longest side is 7 , 7 6 8 must be c, and a or b are 7 and 7 . a2 b2 ¬c2 6

2

7

2

2

1 0 8 7 ¬ 7

36 64 10 0 49 49 ¬ 49 10 0 10 0 49 ¬ 49 10 0 10 0 Since 49 49 , segments with these measures

form a right triangle. However, the three numbers are not whole numbers. Therefore, they do not form a Pythagorean triple. 30.

5 10 15 ? 20

12 24 ? 36 48

13 ? 26 39 52

31. 5-12-13 32. Sample answer: The triples are all multiples of the triple 5-12-13.

197

Chapter 7

m

38. Given: ABC with sides of measure a, A b, and c, where b c2 a2 b2 Prove: ABC is a right triangle. C

41. Let x be the hypotenuse of the triangle with height 26 12 or 38 and base 1 2 (9) or 4.5. 2 2 2 4.5 38 ¬x 20.25 1444 ¬x2 1464.25 ¬x2 1464. 25 ¬x The length of wire needed is 2x 2 1464. 25 or about 76.53 feet. 42. Let s represent the side of each square stone. s2 (2s)2 ¬x2 s2 4s2 ¬152 5s2 ¬225 s2 ¬45 s ¬ 45 or 3 5 The area of each square stone is s2 45, so the area of the walkway is 6 45 or 270 in2. 43. Let x represent the number of miles away from the starting point. 62 122 ¬x2 36 144 ¬x2 180 ¬x2 180 ¬x 13.4 ¬x The trawler traveled about 13.4 miles out of the way. 44. AD BC 6 AD2 AB2 ¬BD2 62 82 ¬BD2 36 64 ¬BD2 100 ¬BD2 100 ¬BD 10 ¬BD

F c a

x

b

B

D

a

E

Proof: Draw DE on line with measure equal to a. At D, draw line m DE. Locate point F on m so that DF b. Draw F E and call its measure x. Because FED is a right triangle, a2 b2 x2. But a2 b2 c2, so x2 c2 or x c. Thus, ABC FED by SSS. This means C DE. Therefore, C must be a right angle, making ABC a right triangle. 39. Given: ABC with right angle at C, AB d Prove: d (x2 x1)2 (y2 y1)2 y

A(x1, y1) d

C (x1, y2) O

B (x2, y2) x

Proof: Statements 1. ABC with right angle at C, AB d 2. (CB)2 (AC)2 (AB)2 3. x2 x1 CB

y2 y1 AC 4. x2 x1 2 y2 y1 2 d2 5. (x2 x1)2 (y2 y1)2 d2 6. (x2 x1)2 (y2 y1)2 d

7. d (x2 x1)2 (y2 y1)2

Reasons 1. Given 2. Pythagorean Theorem 3. Distance on a number line 4. Substitution 5. Substitution

HD BF 8 DM 1 2 (BD) 1 2 (10)

5 DM2 ¬HM2 82 52 ¬HM2 64 25 ¬HM2 89 ¬HM2 89 ¬HM 9.4 ¬HM HM EM FM GM because HD EA FB GC and AC DB so AM BM CM DM. 45. Sample answer: The road, the tower that is perpendicular to the road, and the cables form the right triangles. Answers should include the following. • Right triangles are formed by the bridge, the towers, and the cables. • The cable is the hypotenuse in each triangle. 46. A; let B(8, 0) be the vertex of right triangle ABE. AB2 BE2 ¬AE2 82 h2 ¬102 64 h2 ¬100 h2 ¬36 h ¬ 36 h ¬6

6. Take the square root of each side. 7. Reflexive Property

HD2

40. First, use the Pythagorean Theorem to find the length of the ladder, represented by y. 122 162 ¬y2 144 256 ¬y2 400 ¬y2 400 ¬y 20 ¬y The ladder is 20 feet long. (2 12)2 x2 ¬202 142 x2¬202 196 x2 ¬400 x2 ¬204 x ¬ 204 x ¬2 51 x ¬14.3 The ladder reaches about 14.3 feet up the side of the house.

Chapter 7

198

47. C; x2 36 ¬(9 x)2 x2 36 ¬81 18x x2 36 ¬81 18x 45 ¬18x 2.5 ¬x 48. 3-4-5, 6-8-10, 12-16-20, 24-32-40, 27-36-45 49. 3 4 5 60 6 8 10 480 8 60 12 16 20 3840 64 60 24 32 40 30,720 512 60 27 36 45 43,740 729 60 Yes, the conjecture holds true.

57.

58.

55.

56.

3x

3

27

7.6 1012

2

1.41... 1.18... 1.09... 1.04...

x

4

0.25

4

0.25

1 x

0.25

4

0.25

4

7 3 3 61. 7 3 3

¬36 x ¬36 or 6 Let x represent the x 9 x ¬ 1 2 2 x ¬108 x ¬ 108 or 63 x ¬10.4 Let x represent the 11 x x ¬ 7 x2 ¬77 x ¬ 77 x ¬8.8 Let x represent the x 6 x ¬9 x2 ¬54 x ¬ 54 or 3 6 x ¬7.3 Let x represent the x 2 x ¬7 x2 ¬14 x ¬ 14 x ¬3.7 Let x represent the 2 ¬x x 5 x2 ¬10 x ¬ 10 x ¬3.2

4

The sequence of numbers alternates between 0.25 and 4. 60. No; 12 13 25, so the sides do not satisfy the Triangle Inequality. 3

18 2 18 2 62. 2 92

x2

54.

27

x

59.

3 ¬x x 12

53.

3

1 2 1.41... 1.18... 1.09... 1.04... 1.02... x2 The sequence of numbers converges to 1.

50. Let x represent the geometric mean.

52.

1

The sequence of numbers approaches positive infinity.


51.

x

2

2 28 14 2 63. 2 2 2 2 7 2 7

geometric mean.

3 33 3 33 3 11 64. 3

3

3

24 122 2 24 2 65. 2 2

2 12 3 12 3 66. 3 43 3 3 2 6 3 2 18 67. 3 3 3 2 6 3 22

geometric mean.

geometric mean.

15 3 15 3 68. 3 53 3

3 8 8 2 2 69. 8 8 8 2 4 2 8 2

geometric mean.

10 5 10 25 0 25 1 70. 10 2 10

geometric mean.

7-3

10

Special Right Triangles


x

5

10

2.51...

2.24...

2.11...

2x

10

2.51...

2.24...

2.11...

2.05...

1. Sample answer: Construct two perpendicular lines. Use a ruler to measure 3 cm from the point of intersection on one ray. Use the compass to copy the 3 cm segment. Connect the two endpoints to form a 45°-45°-90° triangle with sides of 3 cm and a hypotenuse of 3 2 cm.

The sequence of numbers converges to 2.

199

Chapter 7

Graph A and B. A B lies on a vertical gridline of the coordinate plane. Since B D will be perpendicular to A B , it lies on a horizontal gridline. AB 3 0 3 B A is the shorter leg. B D is the longer leg. BD 3(AB) BD 3(3) or 3 3 Point D has the same y-coordinate as B. D is located 3 3 units to the right of B or to the left of B. So, the coordinates of D are (8 3 3, 3) or about (13.20, 3) or (8 3 3, 3) or about (2.80, 3).

2. Sample answer: Draw a line using a ruler. Then use a protractor to measure a 90° angle. On one ray mark a 2 cm length, and at that endpoint use the protractor to measure a 30° angle toward the other ray. Where this ray intersects the other ray should form a 60° angle, completing the 30°-60°90° triangle with sides 2 cm, 2 3cm, and a hypotenuse of 4 cm. 3. The diagonal is twice as long as its width w, so the diagonal forms a 30°-60°-90° triangle with the length and the width w. Then the length of the rectangle is 3 times the width, or 3w. 4. The triangle is a 45°-45°-90° triangle. The legs are congruent, so x 3. The length of the hypotenuse is 2 times the length of the leg, so y 3 2. 5. The triangle is a 45°-45°-90° triangle. The legs are congruent, so x y. The length of the hypotenuse is 2 times the length of the leg. 10 ¬x 2

10.

y

D (2, 6 4

B (2, 6)

3)

A(6, 6)

10 ¬x 2 10 2 ¬x 2 2 10 2 ¬x 2

52 ¬x

O

So, x 52 and y 52.

Graph A and B. A B lies on a horizontal gridline of the coordinate plane. Since B D will be perpendicular to A B , it lies on a vertical gridline. AB 2 6 4 B A is the shorter leg. B D is the longer leg. BD 3(AB) BD 3(4) or 4 3 Point D has the same x-coordinate as B. D is located 4 3 units above B. So, the coordinates of D are (2, 6 4 3) or about (2, 12.93). 11. The length of each leg of the 45°-45°-90° triangle formed by homeplate, first base, and second base is 90 feet. The distance d is the hypotenuse and is 2 times as long as a leg. Then d 902 or about 127.28 feet.

6. The triangle is a 30°-60°-90° triangle. y is the measure of the hypotenuse and x is the measure of the longer leg. y 2(8) or 16 x 8 3 7. ABC is a 30°-60°-90° triangle with hypotenuse c, shorter leg a and longer leg b. c 2a 8 2a 4a b 3(a) b 3(4) or 4 3 8. ABC is a 30°-60°-90° triangle with hypotenuse c, shorter leg a and longer leg b. b ¬ 3(a) 18 ¬ 3(a)


18 ¬a 3 18 3 ¬a 3 3 18 3 ¬a 3

12. The figure is a square, so each triangle is a 45°-45°-90° triangle. Thus, x 45. The length of the hypotenuse is 2 times the length of a leg of the triangle. Therefore, y 2(9.6) or 9.6 2. 13. The figure is a square, so each triangle is a 45°-45°-90° triangle. Thus, y 45. the length of the hypotenuse is 2 times the length of a leg of the triangle. 17 ¬x 2

6 3 ¬a c 2a c 2(63 ) c 12 3 9.

17 ¬x 2 17 2 ¬x 2 2 17 2 ¬x 2

y

D (8 3

O

Chapter 7

x

3, 3) B (8, 3)

A(8, 0)

D (8 3

3, 3)

x

200

18. In BCE, a is the measure of the hypotenuse and E C is the longer leg. a ¬2(BE) 10 3 ¬2(BE) 5 3 ¬BE CE ¬ 3(BE) CE ¬ 3 (5 3) CE ¬5 3 or 15 In CEA, AE is the longer leg. y 3(CE) y 3(15) or 15 3 19. In BEC, a is the measure of the hypotenuse and x is the measure of the shorter leg. a 2x a 2(73 ) a 143 CE 3 (x) CE 3 (73 ) CE 7 3 or 21 In ACE, y is the measure of the longer leg and b is the measure of the hypotenuse. y 3 (CE) y 3 (21) or 213 b 2(CE) b 2(21) or 42 20. The altitude is the longer leg of a 30°-60°-90° triangle. Let x represent the length of the shorter leg. 12 3 (x)

14. The triangle is a 30°-60°-90° triangle where x is the measure of the shorter leg and y is the measure of the longer leg. 18 ¬2x 9 ¬x y ¬ 3(x) y ¬ 3(9) or 9 3 15. C

y

12

60

D x A B ABC is equilateral because C D bisects the base and C D is an altitude. Therefore ADC is a 30°-60°-90° triangle with hypotenuse y and shorter leg 2x. x 3 ¬12 2

x ¬12 2 3

24 3 x ¬ 3

3

24 3 x ¬ 3

x ¬83

12 x 3 12 3 x 3 3 12 3 x 3

y 2 2x

yx y 83 16. x is the shorter leg and y is the longer leg of the 30°-60°-90° triangle. 2x ¬11

43 x Then the hypotenuse, which is a side of the equilateral triangle, has measure 2x 2(43 ) or 83 13.86 feet. 21. The perimeter is 45, so each congruent side has 45 measure 3 or 15 cm. An altitude is the longer leg of a 30°-60°-90° triangle. Let x represent the length 15 of the shorter leg. Then x 2 or 7.5. The altitude has measure 3 (x) 7.53 or about 12.99 cm. 22. Each side of the square is a leg of a 45°-45°-90° triangle. The length of the hypotenuse, 222 mm, is 2 times as long as a leg. So each leg has measure 22. Then the perimeter of the square is 4(22) or 88 mm. 23. The altitude is the longer leg of a 30°-60°-90° triangle. Let x represent the length of the shorter leg. 7.4 3 (x)

11 x ¬ 2 or 5.5

y ¬3 (x) y ¬3 (5.5) or 5.53 17.

F y

5

45

G

D

E

x In DEF, D E is the hypotenuse so x 52 . In FGE, F G is a leg and F E is the hypotenuse. 2(y) ¬5

7.4 x 3 7.4 3 x 3 3 7.4 3 x 3

5

y ¬ 2

2 y ¬

5

2

2 5 y ¬ 2

2

Then the hypotenuse, which is a side of the

7.4 3 equilateral triangle, has measure 2x 2 3

14.8 3 or . Thus, the perimeter of the equilateral 3 14.8 3 14.83 or about 25.63 m. triangle is 3 3

201

Chapter 7

24.

d

c 60

30

6

e

4 5 (1) 4 through the midpoint of G H , 2, 2 or (4, 2). GH 5 (1) 6 The diagonal through P also has measure 6. Point P has the same y-coordinate as the midpoint of H G . P is located 3 units to the left or right of the midpoint of G H . So, the coordinates of P are (4 3, 2) (1, 2) or (4 3, 2) (7, 2).

30

a 6

b

60 60

30

60

120

60

6

6

f 60

60

29.

The diagonals determine equilateral triangles with sides equal to half the length of each diagonal, or 6 inches. So e f 6, and e f 3. Then a 3 (e) or 33 , so c d 33 . Then the perimeter of the rectangle is 2(6) 2(33 33 ) or 12 123 32.78 inches. 25 6 25. Each side has measure 4 or 8. The length of a diagonal is 2 times as long as a side of the square. So the measure of a diagonal is 82 11.31. 26. 8 2x 4x y 3 (x) y 3 (4) or 43 z6 Each leg of the 45°-45°-90° triangle has length x, or 4. Then CB 42 . So, the perimeter of ABCD is 43 6 4 42 6 8 43 42 24, or about 36.59 units. 27. y P (4, 8)

A (3, 1 )

y

D(3, 7)

x

P(10.5, 6)

C (3, 6)

Graph C and D. C D lies on a vertical gridline of the coordinate plane. Since P C will be perpendicular to C D , it lies on a horizontal gridline. CD 7 (6) 13 D C is the longer leg. P C is the shorter leg. So, CD 3 (PC). 13 3 (PC) 13 PC 3 13 3 PC 3 3 13 3 PC 3

B ( 4, 1)

Point P has the same y-coordinate as C. P is 13 3 located units to the left of C. So, the 3 13 3 coordinates of P are 3 3 , 6 or about (10.51, 6).

x

Graph A and B. A B lies on a horizontal gridline of the coordinate plane. Since P B will be perpendicular to A B , it lies on a vertical gridline. AB 4 (3) 7 AB and PB are congruent, so PB 7. Point P has the same x-coordinate as B. P is located 7 units above B. So, the coordinates of P are (4, 1 7) or (4, 8). 28.

30. y

P (8, 1.5)

x

y

H (4, 5 )

P

C (2, 5)

Graph C and D. C D lies on a horizontal gridline of the coordinate plane. mC 30, so mD 60. Let Q be the point on C D where the altitude from P intersects CD. Then mCPQ 60. CD 10 2 8 P C is the longer leg, and P D is the shorter leg. 2(PD) CD 2(PD) 8 PD 4 3 (PD) CP 3 (4) CP 43 CP

P

x

G ( 4 , 1 ) Graph G and H. If GH is the diagonal of a square with vertices P, G, and H then the other diagonal is perpendicular to and bisects G H . G H lies on a vertical gridline of the coordinate plane, so the other diagonal through P is horizontal and goes

Chapter 7

D (10, 5)

202

31.

32. 33. 34. 35.

(c) d¬ 3 d¬ 3 (3 ) d¬ 3 d¬ 2e 3¬ 2e 1.5¬ e f¬ 3 (e) f¬ 1.53 f¬ 2g 1.53 ¬ 2g 0.753 ¬ g x¬ 3 (g) x¬ 3 (0.753 ) x¬ 0.75 3 2.25 39. The hexagon consists of six equilateral triangles. So, mUXY 60. WY bisects a 60° angle, so mXYW 30. WY is twice the length of the longer side of a 30°-60°-90° triangle.

CP is the hypotenuse of 30°-60°-90° triangle CPQ. Q C is the longer side and PQ is the shorter side. 2(PQ) CP 2(PQ) 43 PQ 23 3 (PQ) CQ 3 (23 ) CQ 2(3) CQ 6 CQ Q is on CD 6 units to the right of C, so Q has coordinates (2 6, 5) (8, 5). P is 23 units above Q, so P has coordinates (8, 5 23 ). T S is the shorter leg of a 30°-60°-90° triangle. SP 2(ST) 63 2(ST) 33 ST Then c 33 . PT is a vertical line segment, so a c 33 . PT 3 (ST) PT 3 (33 ) PT 3 3 or 9 Then b 9. P Q S R , so PQ is a horizontal line segment. Thus d b 9. 12 triangles The smaller angle is rotated, so it is the 30° angle. There are no gaps because when a 30° angle is rotated 12 times, it rotates 360°. Sample answer:

1 2 WY ¬2 2 3

¬123 ¬20.78 cm 40. Find CB. AB 2 (CB) 347 2 (CB) 34 7 CB 2 3 4 7 2 CB 2 2 347 2 CB 2

347 2 The center fielder is standing or about 2 245.4 feet from home plate.

41.

24

A

E

B 60

36.

8

2x 8 x4 y 3 (x) y 3 (4) or 43 y 2 (z) 43 2 (z)

45

D

a 30

4

c e

b 30 d 30 f 30

C

Draw altitudes C E and A F . BEC is a 30°-60°-90° triangle and DAF is a 45°-45°-90° triangle. In BEC, CB is the hypotenuse and E C is the longer leg. CB 2(EB) 8 2(EB) 4 EB EC 3 (EB) EC 43 AF EC, so AF 43 . DF AF, so DF 43 . AD 2 (DF) AD 2 (43 ) AD 46 FC AE AB EB 24 4 20 The perimeter of ABCD is AB BC DF FC AD 24 8 43 20 46 or 52 43 46 units.

4 3 z 2 4 3 2 z 2 2 6 4 z 2

26 z 37. BD 3 (DH) 83 3 (DH) 8 DH BH 2(DH) BH 2(8) BH 16 38. 4¬ 2a 2¬ a b¬ 3 (a) b¬ 23 b¬ 2c 23 ¬ 2c 3 ¬ c

F

g

x

203

Chapter 7

a2 b2¬ c2 202 482¬ 522 400 2304¬ 2704 2704¬ 2704 Since 2704 2704, the measures satisfy the Pythagorean Theorem. So the sides can be the sides of a right triangle. All side lengths are whole numbers, so the measures form a Pythagorean triple. 49. a2 b2¬ c2 72 242¬ 252 49 576¬ 625 625¬ 625 Since 625 625, the measures satisfy the Pythagorean Theorem. So the sides can be the sides of a right triangle. All side lengths are whole numbers, so the measures form a Pythagorean triple. 50. a2 b2¬ c2 122 342¬ 372 144 1156¬ 1369 1300¬ 1369 Since 1300 1369, the measures do not satisfy the Pythagorean Theorem. So the sides cannot be the sides of a right triangle. The measures do not form a Pythagorean triple.

42. Sample answer: Congruent triangles of different color can be arranged to create patterns. Answers should include the following. • 5, 9, 15, and 17; 3, 4, 6, 7, 10, 11, and 12 • Placing 45° angles next to one another forms 90° angles, which can be placed next to each other, leaving no holes. 43. C; 2x 4x 90 6x 90 x 15 mA 4x 4(15) 60 mB 2x 2(15) 30 BC 3 (AC) 6 3 (AC)

48.

6 AC 3 6 3 AC 3 3 3 6 3 AC

23 AC AB 2(AC) AB 2(23 ) 43

2 2 5 44. (3 ★ 4)(5 ★ 3)¬ 3 42 32

51.

52

4z¬ 100 z¬ 25 y¬ z 4 y¬ 25 4 or 21 y x ¬ 4 x 4y¬ x2 4(21)¬ x2 84¬ x2 84 ¬ x 221 ¬ x 9.2¬ x

¬ 42 25 ¬ 16

Page 363 Maintain Your Skills 45. a2 b2¬ c2 32 42¬ 52 9 16¬ 25 25¬ 25 Since 25 25, the measures satisfy the Pythagorean Theorem, so the sides can be the sides of a right triangle. All side lengths are whole numbers, so the measures form a Pythagorean triple. 46. a2 b2¬ c2 92 402¬ 412 81 1600¬ 1681 1681¬ 1681 Since 1681 1681, the measures satisfy the Pythagorean Theorem. So the sides can be the sides of a right triangle. All side lengths are whole numbers, so the measures form a Pythagorean triple. 47. a2 b2¬ c2 202 212¬ 312 400 441¬ 961 841¬ 961 Since 841 961, the measures do not satisfy the Pythagorean Theorem. So the sides cannot be the sides of a right triangle. The measures do not form a Pythagorean triple.

Chapter 7

z 10 1 0 ¬ 4

52.

12 ¬ x x 8

96¬ x2 96 ¬ x 46 ¬ x

9.8¬ x y 8¬ y 12 8 y2¬ 32 y¬ 32 y¬ 42 y¬ 5.7 12 z z ¬ 12 8

z2¬ 48 z¬ 48 z¬ 43 z¬ 6.9

204

53.

15 5 5 ¬ y

13 62. 0.2 g 0.2g 13 g 65

15y¬ 25 y¬ 5 3 x¬ 15 y

7 63. n 0.25 7 0.25n 28 n m 64. 9 0.8 7.2 m

x¬ 15 5 3 40 x¬ 3

z 15 z¬ x

15x¬ z2

24 65. x 0.4 24 0.4x 60 x

40 2 15 3 ¬ z

200¬ z2

35 66. y¬ 0.07 35¬ 0.07y 500¬ y

200 ¬ z 102 ¬ z

14.1¬ z 54. In ALK and ALN, A L A L , KL N L , and AK AN. Then mALK mALN by the SSS Inequality. 55. In ALK and NLO, A L O L , KL N L , and AK NO. So, mALK mNLO by the SSS Inequality. 56. In OLK and NLO, L O L O , KL N L , and KO NO. So, mOLK mNLO by the SSS Inequality. 57. In KLO and ALN, K L N L , LO A L , and N A K O . KLO ALN by SSS Congruence. So mKLO¬ mALN by CPCTC and the definition of congruent angles. 58. JK [1 (3)]2 (5 2)2 2 2 2 3 13 RS [4 (6)]2 (3 6)2 2 2 2 (3) 13 KL [4 ( 1)]2 (4 5)2 2 2 5 (1) 26 2 ST [1 (4)] (4 3)2 2 12 5 26 JL [4 ( 3)]2 (4 2)2 2 2 7 2 53 RT [1 ( 6)]2 (4 6)2 2 2 7 2) ( 53 JKL RST by SSS. 59. 5¬ 3x 15¬ x 60. 9x 0.14 x 1.26 61.

Page 363 Practice Quiz 1 1. Let x represent the measure of the altitude. 21 x x¬ 7 x2¬ 147 x¬ 147 or 73 x¬ 12.1 2. Let x represent the measure of the altitude. x 9 x¬ 5 x2¬ 45 x¬ 45 or 35 x¬ 6.7 3. AB (4 2 )2 (0 1)2 2 2 2 (1) 5 BC (5 4 )2 (7 0)2 2 2 1 7 50 AC (5 2 )2 (7 1)2 2 2 3 6 45 AB2 AC2¬ BC2 (5 )2 (45 )2¬ (50 )2 5 45¬ 50 50¬ 50 The triangle is a right triangle because the side lengths satisfy the Pythagorean Theorem. 4. x 3 y (2 )3 or 32 5. x 2(6) or 12 y 3 (6) or 63

7-4

10 0.5¬ k

Trigonometry

Page 365 Geometry Activity: Trigonometric Ratios

0.5k¬ 10 k¬ 20

1. They are similar triangles because corresponding sides are proportional.

205

Chapter 7

2.

In AED

In AGF

opposite leg

6. sinA hypotenuse

In ABC

ac

D E FG B C sin A AD 0.6114 AF 0.6114 AC 0.6114

8 1 7 0.47

AE AG AB 0.7913 cos A AD AF 0.7913 AC 0.7913

adjacent leg

cosA hypotenuse

FG D E BC tanA AE 0.7727 AG 0.7727 AB 0.7727

bc 15 17 0.88

3. Sample answer: Regardless of the side lengths, the trigonometric ratio is the same when comparing angles in similar triangles. 4. mA is the same in all triangles.

opposite leg

tanA adjace nt leg a b 8 0.53 15 opposite leg

sinB hypotenuse


bc

1. The triangles are similar, so the ratios remain the same. 2. Sample answer: C

15 17 0.88 adjacent leg

cosB hypotenuse ac

15 35

B

8 0.47 17

A

mB 90, mC 55, b 26.2, c 21.4 3. All three ratios involve two sides of a right triangle. The sine ratio is the measure of the opposite side divided by the measure of the hypotenuse. The cosine ratio is the measure of the adjacent side divided by the measure of the hypotenuse. The tangent ratio is the measure of the opposite side divided by the measure of the adjacent side. 4. The tan is the ratio of the measure of the opposite side divided by the measure of the adjacent side for a given angle in a right triangle. The tan1 is the measure of the angle with a certain tangent ratio.

opposite leg

tanB adjacent leg b a 1 5 8 1.88

7. KEYSTROKES: sin57° 0.8387 8. KEYSTROKES: cos60° 0.5000 9. KEYSTROKES: cos33° 0.8387 10. KEYSTROKES: tan30° 0.5774 11. KEYSTROKES: tan45° 1.0000 12. KEYSTROKES: sin85° 0.9962 13. KEYSTROKES: mA 54.8 14. KEYSTROKES: mB 39.1 15. y

opposite leg

5. sinA hypotenuse ac 14 50 0.28 adjacent leg

cosA hypotenuse bc 48 50 0.96 opposite leg tanA adjace nt leg a b 14 48 0.29 opposite leg sinB hypotenuse b c 48 50 0.96 adjacent leg cosB hypotenuse a c 14 50 0.28 opposite leg tanB adjace nt leg b a 48 14 3.43

Chapter 7

SIN 57 ENTER COS 60 ENTER COS 33 ENTER TAN 30 ENTER TAN 45 ENTER SIN 85 ENTER 2nd [TAN1] 1.4176 ENTER 2nd [SIN1] 0.6307 ENTER

C(0, 6)

B(4, 2)

A(6, 0) x

Explore: You know the coordinates of the vertices of a right triangle and that C is the right angle. You need to find the measure of one of the angles. Plan: Use the Distance Formula to find the measure of each side. Then use one of the trigonometric ratios to write an equation. Use the inverse to find mA.

206

KEYSTROKES: 2nd [TAN1] 1 2 ENTER mB 26.56505118 The measure of B is about 26.6. Examine: Use the sine ratio to check the answer.

Solve: AB (4 6)2 (2 0 )2 100 4 104 or 226 2 BC [0 ( 4)] (6 2)2 16 6 1 32 or 42 2 (6 AC (0 6) 0)2 36 6 3 72 or 62 Use the tangent ratio.

AC sinB AB

sinB 4 or 1 4 5

5

B sin 1 1

5

KEYSTROKES: 2nd [SIN1] 1 2nd [2 ] 5 ENTER mB 26.56505118 The answer is correct. 17. Let x be Maureen’s distance from the tower in feet.

B C tanA AC

4 2 tanA or 2 3 62

A tan12 3

1815 tan31.2 x

KEYSTROKES: 2nd 2 3 ENTER mA 33.69006753 The measure of A is about 33.7. Examine: Use the sine ratio to check the answer. [TAN1]

1815 x tan 3 1.2

KEYSTROKES: 1815 TAN 31.2 ENTER Maureen is about 2997 feet from the tower.

BC sinA AB

4 2 sinA 2 26

Pages 368–370

2 26

4 2 A sin 1

KEYSTROKES: 2nd [SIN1] 4 2nd [2 ] 2 ) ( 2 2nd [2 ] 26 ) ) ) mA 33.69006753 The answer is correct. 16.

y

Practice and Apply

opposite leg 18. sinP hypotenuse p r 12 37 0.32 adjacent leg cosP hypotenuse q r 35 37 0.95 opposite leg tanP adjace nt leg p q 12 35 0.34 opposite leg sinQ hypotenuse q r 35 37 0.95 adjacent leg cosQ hypotenuse p r 12 37 0.32 opposite leg tanQ adjace nt leg q p

B(7 , 5 )

x

A(3 , 3 ) C(7 , 3 ) Explore: You know the coordinates of the vertices of a right triangle and that C is the right angle. You need to find the measure of one of the angles. Plan: Use the Distance Formula to find the measure of each side. Then use one of the trigonometric ratios to write an equation. Use the inverse to find mB. Solve: AB (7 3 )2 [5 (3)] 2 16 4 6 80 or 45 2 BC (7 ) 73 ( 5)2 0 64 or 8 2 [ AC (7 3) 3 ( 3)]2 16 0 or 4 Use the tangent ratio.

35

12 2.92

AC tanB B C 1 tanB 4 8 or 2

B tan12 1

207

Chapter 7

opposite leg

opposite leg

19. sinP hypotenuse

sinQ hypotenuse q

p

r

r 3 3

6 2

2 3

32 2 3 3 0.58 adjacent leg cosP hypotenuse a r 2 3 2 2 32 6 3 0.82 opposite leg tanP adjace nt leg p q 6 3 23 3 2 2 0.71 opposite leg sinQ hypotenuse q r 2 3 2 2 32 6 3 0.82 adjacent leg cosQ hypotenuse p r 6 2 32 2 3 3 0.58 opposite leg tanQ adjace nt leg q p 2 3 6 6 6

3

2 0.87 adjacent leg

cosQ hypotenuse p

r

3

2 3

1 2 0.50 opposite leg

tanQ adjace nt leg q

p

3 1.73 opposite leg

21. sinP hypotenuse p

r 2 3 33


cosP hypotenuse q

r

15 3

33 3 5 3 0.75 opposite leg tanP adjace nt leg p q 3 2 1 5 15 15 5 2 5 0.89 opposite leg sinQ hypotenuse q r 15 3 33 3 5 3 0.75 adjacent leg cosQ hypotenuse p r 2 3 33 2 3 0.67 opposite leg tanQ adjace nt leg q p 15 3 23 3 5 2 1.12

2 1.41 opposite leg

20. sinP hypotenuse p

r 3

2 3


cosP hypotenuse ar 3 3

2 3

3 2 0.87 opposite leg

tanP adjace nt leg p

q

3 2 3 3 2

3

3 0.58

Chapter 7

3 3 2 3 2

208

opposite leg

36. tanx° adjace nt leg

22. KEYSTROKES: SIN 6 ENTER sin6° 0.1045 23. KEYSTROKES: TAN 42.8 ENTER tan42.8° 0.9260 24. KEYSTROKES: COS 77 ENTER cos77° 0.2250 25. KEYSTROKES: SIN 85.9 ENTER sin85.9° 0.9974 26. KEYSTROKES: TAN 12.7 ENTER tan12.7° 0.2254 27. KEYSTROKES: COS 22.5 ENTER cos22.5° 0.9239

25 5 5.0000 37. KEYSTROKES: 2nd [SIN1] 0.7245 ENTER mB 46.42726961 The measure of B is about 46.4.

38. KEYSTROKES: 2nd [COS1] 0.2493 ENTER mC 75.56390633 The measure of C is about 75.6. 39. KEYSTROKES: 2nd [TAN1] 9.4618 ENTER mE 83.96691253 The measure of E is about 84.0. 40. KEYSTROKES: 2nd [SIN1] 0.4567 ENTER mA 27.17436867 The measure of A is about 27.2.

opposite leg

28. sinA¬ hypotenuse 2 6 ¬ 26

41. KEYSTROKES: 2nd [COS1] 0.1212 ENTER mD 83.03863696 The measure of D is about 83.0.

¬ 0.1961 opposite leg 29. tanB adjace nt leg 5 26 or 5 1 1 26

42. KEYSTROKES: 2nd [TAN1] 0.4279 ENTER mF 23.16608208 The measure of F is about 23.2.

5.0000

adjacent leg

30. cosA¬ hypotenuse

43.

26 5 ¬ 26

¬ 0.9806 opposite leg

31. sinx°¬ hypotenuse

x tan24° 1 9 19tan24° x KEYSTROKES: 19 TAN 24 ENTER x 8.5

12 44. sinx° 17

25 ¬

12 x° sin1 17

5 26 25 2 6 ¬ 5 26 26 2 6 25 ¬ 5(26) 26 5 ¬ 26

KEYSTROKES: 2nd [SIN1] 12 17 ENTER x 44.9 x cos62° 6 0 60cos62° x KEYSTROKES: 60 COS 62 ENTER x 28.2 x 46. cos31° 3 4 34cos31° x KEYSTROKES: 34 COS 31 ENTER x 29.1

45.

¬ 0.9806 adjacent leg

32. cosx°¬ hypotenuse 5 5 26 5 2 6 ¬ 526 26 2 6 ¬ 26

¬

6.6 47. sin17° x

¬ 0.1961

6. 6 x sin 1 7°

opposite leg

33. tanA adjace nt leg

KEYSTROKES: 6.6 SIN 17 ENTER x 22.6

2 6 5 26 1 5

15 48. tanx° 18

0.2000

15 x° tan1 18

adjacent leg 34. cosB¬ hypotenuse 2 6 ¬ 26

KEYSTROKES: 2nd [TAN1] 15 18 ENTER x 39.8

¬ 0.1961 opposite leg

35. siny°¬ hypotenuse 1 ¬ 26

2 6 ¬ 1 26 6 ¬ 226

26

¬ 0.1961

209

Chapter 7

41

49. Let x represent the vertical change of the plane after climbing at a constant angle of 3° for 60 ground miles. x tan3° 60 60tan3° x KEYSTROKES: 60 TAN 3 ENTER x 3.1 The plane is about 3.1 1 or 4.1 miles above sea level. 50. Let x represent the maximum height. x sin75°¬ 20 20sin75°¬ x KEYSTROKES: 20 SIN 75 ENTER x 19.32 The ladder can reach a maximum height of about 19.32 feet. 51. Let x represent the distance from the base of the ladder to the building. x cos75° 20 20cos75° x KEYSTROKES: 20 COS 75 ENTER x 5.18 The base of the ladder is about 5.18 feet from the building. 52.

5 J sin 1

KEYSTROKES: 2nd [SIN1] 5 2nd [2 ] 41 ENTER mJ 51.34019175 The answer is correct. 53.

x

C(6 , 5 ) B(1 , 5 ) Explore: You know the coordinates of the vertices of a right triangle and that B is the right angle. You need to find the measure of one of the angles. Plan: Use the Distance Formula to find the measure of each side. Then use one of the trigonometric ratios to write an equation. Use the inverse to find mC. Solve: BC [6 (1)]2 [ 5 (5)] 2 25 0 or 5 BD [1 (1)]2 [2 (5)] 2 0 49 or 7 2 [2 CD [1 (6)] (5)] 2 25 9 4 74

y

J(2, 2)

BD

x

C(2, 2)

D(1 , 2 ) y

tanC B C tanC 7 5

L(7 , 2 )

C tan17 5

KEYSTROKES: 2nd [TAN1] 7 5 ENTER mC 54.46232221 The measure of C is about 54.5. Examine: Use the sine ratio to check the answer.

Explore: You know the coordinates of the vertices of a right triangle and that C is the right angle. You need to find the measure of one of the angles. Plan: Use the Distance Formula to find the measure of each side. Then use one of the trigonometric ratios to write an equation. Use the inverse to find mJ. 2 ( Solve: JC (2 2) 2 2)2 0 16 or 4 CL (7 2 )2 [ 2 (2)] 2 25 0 or 5 JL (7 2 )2 ( 2 2)2 25 6 1 41

BD sinC CD 7 74

sinC

74

7 C sin 1

KEYSTROKES: 2nd [SIN1] 7 2nd [2 ] 74 ENTER mC 54.46232221 The answer is correct. 54.

y

Z(0 ,

35)

C L tanJ JC tanJ 5 4

J tan15 4

X(5 , 0 )

KEYSTROKES: 2nd [TAN1] 5 4 ENTER mJ 51.34019175 The measure of J is about 51.3. Examine: Use the sine ratio to check the answer.

x

Explore: You know the coordinates of the vertices of a right triangle and that Z is the right angle. You need to find the measure of one of the angles.

C L sinJ JL

sinJ 5 41

Chapter 7

Y(7 , 0 )

210

5 6 tany° 24

Plan: Use the Distance Formula to find the measure of each side. Then use one of the trigonometric ratios to write an equation. Use the inverse to find mX. 2 Solve: XY [7 (5)] (0 0)2 144 0 or 12 2 ( YZ (0 7) 0 35 )2 49 5 3 84 or 221 2 XZ [0 (5)] (3 5 0)2 25 5 3 60 or 215

5 tany° 4

5 y° tan1 4

KEYSTROKES: 2nd [TAN1] 2nd [2 ] 5 ) 4 ENTER y 29.2 57.

x tan55°¬ 1 2

12tan55°¬ x KEYSTROKES: 12 TAN 55 ENTER x 17.1 sin47° xy

X Z cosX XY

x y sin 47°

KEYSTROKES: 12 TAN 55 ) SIN 47 ENTER y 23.4

15 2 15 cosX 12 or 6 15 X cos1 6

KEYSTROKES: 2nd [COS1] 2nd [2 ] 15 ) 6 ENTER mX 49.79703411 The measure of X is about 49.8. Examine: Use the sine ratio to check the answer.

24 58. tan32° x 24 x tan 32°

KEYSTROKES: 24 TAN 32 ENTER x 38.4 y cos32° x xcos32° y KEYSTROKES: 24 TAN 32 ) COS 32 ENTER y 32.6 59. Let d represent the distance between Alpha Centauri and the sun. 1 tan0.00021 d

YZ sinX XY

21 2 21 sinX 12 or 6

21 X sin 1 6

KEYSTROKES: 2nd [SIN1] 2nd [2 ] 21 ) 6 ENTER mX 49.79703411 The answer is correct.

1 d tan0.00021

55. A

35

KEYSTROKES: 1 TAN 0.00021 ENTER d 272,837 The distance is about 272,837 astronomical units. 60. The stellar parallax would be too small. 61. Let E be the point where D B intersects A C . EAB is a 45°-45°-90° triangle because it is an isosceles right triangle. AB 2 (AE) 8 2 (AE)

20

B

C

CB sin35° 2 0 20sin35° CB KEYSTROKES: 20 SIN 35 ENTER CB 11.5 AC cos35°¬ 20 20cos35°¬ AC KEYSTROKES: 20 COS 35 ENTER AC 16.4 The perimeter is about 20 11.5 16.4 or 47.9 inches.

8 AE 2 2 8 AE 2 2

42 AE AE sinx° AD

2 4 sinx° 10

2 2 sinx° 5 62. Sample answer: Surveyors use a theodolite to measure angles to determine distances and heights. Answers should include the following. • Theodolites are used in surveying, navigation, and meteorology. They are used to measure angles. • The angle measures from two points, which are a fixed distance apart, to a third point.

24 56. sinx° 36

24 x° sin1 36

KEYSTROKES: 2nd [SIN1] 24 36 ENTER x 41.8 Let a represent the side of the smaller triangle opposite the angle of measure y. (2a)2 242¬ 362 4a2 576¬ 1296 4a2¬ 720 a2¬ 180 a¬ 180 or 65

211

Chapter 7

63. C; (AC)2 32 52 (AC)2 9 25 (AC)2 16 AC 16 or 4 AC cosC BC

73.

cosC 4 5

64. B; x2 152 242 15(24) x2 225 576 360 x2 441 x 441 x 21 5 4 5 65. cscA 5 3 ; secA 4 ; cotA 3 ; cscB 4 ;

74.

3 secB 5 3 ; cotB 4

13 1 3 1 3 5 66. cscA 12 ; secA 5 ; cotA 12 ; cscB 5 ; 13 12 secB 12 ; cotB 5

75.

3 2 8 or 67. cscA 8 3 ; 4 or 2; secA 4 3

3 3 4 2 ; cscB 8 or cotA 4 or 3 3 ; 4 3

3 4 or secB 8 3 4 or 2; cotB 4 3 68. cscA 4 or 2 ; secA 4 or 2 ; 22 2 2 2 2 4 cotA or 1; cscB or 2 ; 22 22 4 2 2 ; cotB or 1 secB or 2 22 22

Page 370

76.


69. b 3 a b 3 (4) or 43 c 2a c 2(4) or 8 70. b 3 a 3 3 a 3 a

77. 78. 79. 80.

3 3 3 a 3 3

81.

3 a c 2a c 23 71. c¬ 2a 5¬ 2a 2.5¬ a b¬ 3 a b¬ 3 (2.5) or 2.53 72. a2 b2¬ c2 42 52¬ 62 16 25¬ 36 41¬ 36 Since 41 36, the measures cannot be the sides of a right triangle because they do not satisfy the Pythagorean Theorem. The measures do not form a Pythagorean triple.

82.

a2 b2¬ c2 52 122¬ 132 25 144¬ 169 169¬ 169 Since the side measures satisfy the Pythagorean Theorem, they can be the sides of a right triangle. The measures are all whole numbers, so they do form a Pythagorean triple. a2 b2¬ c2 92 122¬ 152 81 144¬ 225 225¬ 225 Since the side measures satisfy the Pythagorean Theorem, they can be the sides of a right triangle. The measures are all whole numbers, so they do form a Pythagorean triple. a2 b2¬ c2 82 122¬ 162 64 144¬ 256 208¬ 256 Since 208 256, the measures cannot be the sides of a right triangle because they do not satisfy the Pythagorean Theorem. The measures do not form a Pythagorean triple. Rewrite 4 : 11 as 4x : 11x and use those values for the number of minutes of commercials and actual show. 4x 11x¬ 30 15x¬ 30 x¬ 2 4x 4(2) or 8 8 minutes are spent on commercials. m15 117 vertical m7 30 corresponding m3 30 180 linear pair m3 150 m12 117 180 linear pair m12 63 m11 m12 alternate interior m11 63 m4 30 180 linear pair m4 150

7-5

Angles of Elevation and Depression

Page 373 Check for Understanding 1. Sample answer: ABC A B

C

Chapter 7

212

2. Sample answer: An angle of elevation is called that because the angle formed by a horizontal line and a segment joining two endpoints rises above the horizontal line. 3. The angle of depression is FPB and the angle of elevation is TBP. 4. B

7. The angle of depression between the top of the tower and the horizontal is 12°. Find the distance along the ground from the plane to the tower. D C

x

A 150 ft B

Because D A and C B are horizontal, they are parallel. Thus, DAC ACB. So mACB 12. 15 0 tan12°¬ CB CBtan12°¬ 150 15 0 CB¬ tan 12°

10,000 ft

plane A

12

C

CB¬ 706 The plane is about 706 feet from the base of the tower.

10,000 ft

50 mi

Pages 374–376

AC is 50 miles or 50(5280) 264,000 feet. Let x represent mCAB.

8.

C

7.6 m

x

18.2 m

C

Let x represent mACB. AB tanx°¬ BC 7.6 x¬ tan1 18 .2

x¬ 22.7 The angle of elevation is 22.7°. 6. The angle of depression between the ship and the horizontal is 13.25°. Find the length along the ocean floor.

BC¬ 338.30 AC BC 610.83 338.30 or about 273. The distance between the boats is about 273 m. 9. The angle of elevation between the green and the horizontal is 12°. Let d represent the distance from the tee to the hole. 36 sin12°¬ d dsin12°¬ 36 36 d¬ sin 1 2°

B 40 m

diver D

A

AC¬ 610.83 75 tan12.5°¬ BC BCtan12.5°¬ 75 75 BC¬ tan 1 2.5°

7.6 tanx°¬ 18 .2

13.25

B

The parasailer is at P and the boats are at A and B. PCB and PCA are right triangles. The distance between the boats is AB or AC BC. Because PD and CA are horizontal lines, they are parallel. Thus, DPA PAC and DPB PBC because they are alternate interior angles. This means that mPAC 7 and mPBC 12.5. 75 tan7°¬ AC ACtan7°¬ 75 75 AC¬ tan 7°

A

A

D

75 m

x¬ 2.2 The angle of elevation should be about 2.2°. 5. sun

ship

P 7 12.5

C B tanx°¬ AC 10,0 00 tanx°¬ 264,000 10,0 00 x¬ tan1 264,0 00

B

Practice and Apply

C

The ocean floor and the horizontal level with the ship are parallel, creating congruent alternate interior angles BAC and ACD. 40 tan13.25°¬ D C DC tan13.25°¬ 40 40 DC¬ tan13 .25°

d¬ 173.2 The distance is about 173.2 yards.

DC¬ 169.9 The diver must walk about 169.9 meters along the ocean floor.

213

Chapter 7

10.

H

60 tan8°¬ A F AFtan8°¬ 60 60 AF¬ tan8°

G

500 m

P

Q

11 km

AF¬ 426.92 60 tan11°¬ AM AMtan11°¬ 60 60 AM¬¬ tan11°

The angle of depression between the horizontal and the flight of the helicopter H to the landing pad P is GHP. The ground and the horizontal from the helicopter are parallel. Therefore, mGHP mHPQ since they are alternate interior angles. Let x mHPQ.

AM¬ 308.67 AF AM 426.92 308.67 or about 118.2 yards. The merry-go-round and the Ferris wheel are about 76.4 yards apart.

0. 5 tanx°¬ 11

0. 5 x¬ tan1 11

vertical rise

14 0 14. horizontal distance 2000

x¬ 2.6 The angle of depression is about 2.6°. 11.

0.07 or 7% The grade of the highway is 7%.

A

D

300 yd

27.6 yd

x

15.

B

x

B

The angle of depression between the horizontal and the sledding run is DAC. The horizontals from the top of the run and the bottom of the run are parallel. Therefore, mDAC mACB since they are alternate interior angles. Let x mACB.

C

2000 ft

Let x represent mACB. 140 tanx° ¬ 20 00 140 x ¬tan1 20 00

x ¬4.00 The angle of elevation is about 4°.

27 .6 sinx°¬ 300

16.

27 .6 x¬ sin1 300

x¬ 5.3 The angle of depression is about 5.3°. 12.

A 140 ft

C

A

1100 ft

A 24.4

635 ft

C

B

369.39 ft

1100 sin24.4° ¬ AC

ACsin24.4° ¬1100

x C

B

1100 AC ¬ sin 2 4.4°

Let x represent mACB.

AC ¬2663¬ The ski run is about 2663 feet.

369 .39 sinx°¬ 635 369 .39 x¬ sin1 635

17.

S

x¬ 35.6 The angle of elevation (incline) is about 35.6°. 13.

R

175 ft

B 8

11

K

60 yd

F A

M

200 ft

G

KE and F G are parallel, so KF EG. Since SG is 175 feet and EG is 6 feet, SE is 169 feet. Let x represent mSKE.

F

RAM and RAF are right triangles. The distance between the merry-go-round M and the Ferris wheel F is MF or AF AM. Because RB and AF are horizontal lines, they are parallel. Thus, BRF RFA and BRM RMA because they are alternate interior angles. This means that mRFA 8 and mRMA 11.

Chapter 7

E

6 ft

16 9 tanx° ¬ 200 16 9 x ¬tan1 200

x ¬40.2¬ The angle of elevation is about 40.2°.

214

18.

The raised end of the treadmill is about 8.3 inches off the floor.

S

22. R 123 ft

K

37

F P RP 10 and RF 48. Let x mRFP.

E

6 ft

G

F

R P sinx° ¬ RF 10 sinx° ¬ 48

KE and F G are parallel, so KF EG. Since SG is 123 feet and EG is 6 feet, SE is 117 feet. 11 7 tan37° ¬ KE KEtan37° ¬117

10 x ¬sin1 48 ¬

x ¬12¬ The incline of the treadmill is about 12°. 23. Let xi represent the rise at each stage i, i 1, 2, 3, 4, 5. The length of the treadmill is 48 inches. Suppose the incline at the beginning of the exam is 10°. x1 Stage 1: sin10°

11 7 KE ¬ tan 37° ¬

KE ¬155.3¬ KE FG, so the distance between kirk and the geyser is about 155.3 feet. 19. D

48

x1 48sin10° x1 8.3351 60

C

x 48

30

A

2 Stage 2: sin12°

B

x2 48sin12° x2 9.9798

200 ft

D C tan60° ¬ AC ACtan60° ¬DC

x 48

3 Stage 3: sin14°

x3 48sin14° x3 11.6123

D C tan30° ¬ BC

x 48

ACta n60° tan30° ¬ BC

4 Stage 4: sin16°

BCtan30° ¬ACtan60° n 60° AC ta BC ¬ tan 30° tan 60° AC 200 ¬AC tan 30°

x4 48sin16° x4 13.2306 x 48

5 Stage 5: sin18°

x5 48sin18° x5 14.8328 x2 x1 9.9798 8.3351 1.6447 x3 x2 11.6123 9.9798 1.6325 x4 x3 13.2306 11.6123 1.6183 x5 x4 14.8328 13.2306 1.6026 No, the end of the treadmill does not rise the same distance each time. The changes in the rise of the treadmill between stages are only approximately the same, about 1.6 inches.

AC 200 ¬AC(3) 200 ¬3AC AC 200 ¬2AC 100 ¬AC BC ¬AC 200 ¬100 200 or 300 The observers are 100 feet and 300 feet from the base of the tree. 20. Let x represent the distance from the spotlight to the base of the cloud formation. x tan62.7° ¬ 8 3 83tan62.7° ¬x 160.8 ¬x The ceiling is about 160.8 1.5 or 162.3 meters.

24. D

21. R 15.85

25.6

F P RF 48 and mRFP 10. Find RP.

C

B 0.5 km A

R P sin10° ¬ RF R P sin10° ¬ 48

D C tan25.6° ¬ BC BCtan25.6° ¬DC

48sin10° ¬RP¬ 8.3 ¬RP¬

D C tan15.85° ¬ AC

215

Chapter 7

ACtan15.85° ¬DC ACtan15.85° ¬BCtan25.6°

tan 52° AD ¬DC tan 33°

tan 52° 7 DC ¬DC tan 33°

tan 25.6° AC ¬BC tan 15 .85° Change AC to meters. 0.5 km 500 m

tan 52° 7 ¬DC tan 33° DC tan 52° 7 ¬DC tan 33° 1

tan 25.6° 500 BC ¬BC tan 15 .85° t a n 2 5 .6° 500 ¬BC tan 15 .85° BC tan 25.6° 500 ¬BC tan 15 .85° 1 500 BC ¬ tan 25.6° tan 15 .85° 1

7

tan 52° DC tan 33° 1 ¬

A 16

29

3 mi

D

B

n

C

12 0 tan25° ¬ x xtan25° ¬120

f Find f n. A E is parallel to D B , so EAD ADB and EAC ACB because they are alternate interior angles. Then mADB 16 and mACB 29.

120 x ¬ tan 25°

x ¬257.3 The ship is about 257.3 meters from the tower. y x 29. A; ¬ 1 6 28 16y ¬28x

tan16° ¬3f f tan16° ¬3

161 2 ¬28x

3 f ¬ tan 16° 3 tan29° ¬ n

8 ¬28x

8 ¬x 28 2 ¬x 7

ntan29° ¬3 3 n ¬ tan 29° 3 3 f n ¬ tan 16° tan 29° f n ¬5.1 The crater is about 5.1 miles across.

26.

Page 376

52

33

7 mi

C

D

BD tan33° ¬ AD

ADtan33° ¬BD BD tan52° ¬ DC DCtan52° ¬BD ADtan33° ¬DCtan52°

Chapter 7


30. cosA ¬0.6717 A ¬cos1(0.6717) A ¬47.8 31. sinB ¬0.5127 B ¬sin1(0.5127) B ¬30.8 32. tanC ¬2.1758 C ¬tan1(2.1758) C ¬65.3 33. cosD ¬0.3421 D ¬cos1(0.3421) D ¬70.0 34. sinE ¬0.1455 E ¬sin1(0.1455) E ¬8.4 35. tanF ¬0.3541 F ¬tan1(0.3541) F ¬19.5

B

A

tan 33°

BD ¬3.0 The balloon is about 3.0 miles above the ground. 27. Answers should include the following. • Pilots use angles of elevation when they are ascending and angles of depression when descending. • Angles of elevation are formed when a person looks upward and angles of depression are formed when a person looks downward. 28. B; let x represent the distance from the ship to the foot of the tower.

BC ¬727 DC ¬BCtan25.6° ¬348 Ayers Rock is about 348 meters high. 25. E

7 tan52° tan 52° BD ¬ 1

216

36.

28 7 47. 15 ¬ x 28x ¬15(7) 28x ¬105 x ¬3.75

12 ¬x2 12 ¬x 2 12 2 x 2 2 122 ¬x 2

x 3 48. 4 0 ¬ 2 6

26x ¬40(3) 26x ¬120 60 x ¬ 13

62 ¬x y ¬x y ¬62 37. x 143 y 2(14) or 28 38. 20 2y 10 y x ¬y3 x ¬103 39. Let be the length of the model.

Pages 380–381

90 ¬78(36) 90 ¬2808 ¬31.2 The length of the model is 31.2 cm. 40a. 1 2 40b. AAS 40c. F X G X 40d. CPCTC 40e. 4 3 40f. Isosceles Triangle Theorem

e

D

f

E

sin 6 5° d 15. Then 15 is the fixed ratio or scale factor for the Law of Sines extended proportion. sin 6 5° sin 73° The length of e is found by using e. 15

The mF is found by evaluating 180 (mD mE). In this problem mF 42. The length of f sin 6 5° sin 42° is found by using f. 15

x 5 6 ¬ 3 42

3. In one case you need the measures of two sides and the measure of an angle opposite one of the sides. In the other case you need the measures of two angles and the measure of a side.

5 3 x ¬ 4 5

3(45) ¬5x 135 ¬5x 27 ¬x

4.

12 24 43. 17 ¬ x 12x ¬17(24) 12x ¬408 x ¬34

44.

d

Sample answer: Let mD 65, mE 73, and

42x ¬6(35) 42x ¬210 x ¬5 42.


1. Felipe; Makayla is using the definition of the sine ratio for a right triangle, but this is not a right triangle. 2. F

length of model wingspan of model length of plane wingspan of plane 3 6 7 8 ¬ 90

41.

The Law of Sines

7-6

X sin sin Y x ¬y sin 37° sin 68° ¬ y 3

ysin37° ¬3sin68° 3 sin 68° y ¬ sin 37°

y ¬4.6 5. mX mY mZ ¬180 57 mY 72 ¬180 mY ¬51

24 x 36 ¬ 15

24(15) ¬36x 360 ¬36x 10 ¬x

X sin sin Y x ¬y sin 57° sin 5 1° x ¬ 12.1

12 48 45. 13 ¬ x

12x ¬13(48) 12x ¬624 x ¬52

12.1sin57° ¬xsin51° 12.1 si n 57° sin 51° ¬x

13.1 ¬x

x 5 46. 1 8 ¬8 8x ¬18(5) 8x ¬90 x ¬11.25

217

Chapter 7

6.

Y sin sin Z y ¬z sin Y sin 3 7° 7 ¬ 11

10. mP mQ mR ¬180 33 mQ 58 ¬180 mQ 91 ¬180 mQ ¬89

11sinY ¬7sin37° 7sin 37° sinY ¬ 11

P sin sinQ p ¬q sin 33° sin 8 9° p ¬ 22

7sin 37° Y ¬sin1 11 Y ¬23°

22sin33° ¬psin89°

Y sin sin Z y ¬¬z sin 9 2° sin Z 17 ¬ 14

7.

22 sin 33° sin 89° ¬p

12.0 ¬p

14sin92° ¬17sinZ

R sin sin Q r ¬q sin 58° sin 8 9° r ¬ 22

14sin 92° ¬sinZ 17 14s in 92° ¬Z 17

sin1

22sin58° ¬rsin89°

55° ¬Z

22 sin 58° sin 89° ¬r

8. mP mQ mR ¬180 mP 59 66 ¬180 mP 125 ¬180 mP ¬55

18.7 ¬r

P sin sin Q p ¬q sin 5 5° sin 59° 72 ¬ q

22sin120° ¬28sinQ 22sin 120° ¬sinQ 28 22si n 120° ¬Q 28

qsin55° ¬72sin59°

sin1

72 sin 59° q ¬ sin 55° P sin sin R p ¬r sin 5 5° sin 66° 72 ¬ r

rsin55° ¬72sin66°

P sin sin R p ¬r sin 1 20° sin 17° ¬ r 28

72 sin 66° r ¬ sin 55°

r ¬80.3

rsin120° ¬28sin17°

P sin sin R p ¬r sin 1 05° sin R ¬ 32 11

28 sin 17° r ¬ sin 120°

r ¬9.5

11sin105° ¬32sinR

12. mP mQ mR ¬180 50 65 mR ¬180 115 mR ¬180 mR ¬65

11sin 105° ¬sinR 32 11si n 105° ¬R 32

sin1

43° ¬Q mP mQ mR ¬180 120 43 mR ¬180 163 mR ¬180 mR ¬17

q ¬75.3

9.

P sin sin Q p ¬q sin 1 20° sin Q ¬ 28 22

11.

19° ¬R mP mQ mR ¬180 105 mQ 19 ¬180 mQ 124 ¬180 mQ ¬56

P sin sin Q p ¬q sin 5 0° sin 65° 12 ¬ q

qsin50° ¬12sin65° 12 sin 65° q ¬ sin 50°

P sin sinQ p ¬q sin 1 05° sin 56° ¬ q 32

q ¬14.2 P sin sin R p ¬r sin 5 0° sin 65° 12 ¬ r

qsin105° ¬32sin56° 32 sin 56° q ¬ sin 105°

rsin50° ¬12sin65°

q ¬27.5

12 sin 65° r ¬ sin 50°

r ¬14.2

Chapter 7

218

Q sin sin R q ¬r sin 11 0.7° sin R ¬ 17.2 9.8

13.

9.8sin110.7° ¬17.2sinR

10.5sin73° ¬18.2sinM

9.8sin 110.7° ¬sinR 17.2 9.8si n 1 10.7° ¬R 17.2

10.5 si n 73° ¬sinM 18.2 10.5 s i n 73° ¬M 18.2

sin1

sin1

32° ¬R mP mQ mR ¬180 mP 110.7 32 ¬180 mP 142.7 ¬180 mP ¬37

K sin sinM k ¬m sin M sin 9 6° 10 ¬ 4.8

4.8sin96° ¬10sinM 4.8si n96° ¬sinM 10 4.8s i n96° ¬M 10

sin1

17.2sin37° ¬psin110.7° 17.2 sin 37° sin 110.7° ¬p

11.1 ¬p 14. AD B C , so DAC BCA because they are alternate interior angles. Thus, mDAC 88.

29° ¬M mM ¬29

20. mK mL mM ¬180 31 88 mM ¬180 119 mM ¬180 mM ¬61

sin 32° sin8 8° ¬ D C 6

DCsin32° ¬6sin88°

sin L sinM ¬m sin 88° sin 6 1° ¬ 5.4

6 sin 88° DC ¬ sin 32° DC ¬11.3 ABCD is a parallelogram, so A D B C and C D A B . The perimeter of ABCD is 2(6) 2(11.3), or 34.6 units. 15. mA mB mC ¬180 55 mB 62 ¬180 mB 117 ¬180 mB ¬63

5.4sin88° ¬sin61° 5.4 si n 88° sin 61° ¬

6.2 ¬ sinM sin L m ¬ sin 5 9° sin L 14.8 ¬ 8.3

21.

8.3sin59° ¬14.8sinL

sin 6 3° sin 6 2° 240 ¬ AB

8.3 sin 59° ¬sinL 14.8 8.3 s in 59° ¬L 14.8

ABsin63° ¬240sin62°

sin1

240 si n 62° AB ¬ sin 63° AB ¬237.8 feet

22.

Pages 381–382 Practice and Apply K sin sin L k ¬ sin 63° sin 4 5° k ¬ 22

29° ¬L mL ¬29


7.4sin41° ¬xsin71° 7.4 si n 41° sin 71° ¬x

5.1 ¬x

22sin63° ¬ksin45° 22 sin 63° sin 45° ¬k

mW mX mY ¬180 mW 41 71 ¬180 mW 112 ¬180 mW ¬68

27.7 ¬k 17.

33° ¬M mM ¬33

19.

P sin sin Q p ¬q sin 37° sin 11 0.7° p ¬ 17.2

16.

K sin sinM k ¬m sin 7 3° sin M 18.2 ¬ 10.5

18.

K sin sin L k ¬ sin 7 0° sin 52° 3.2 ¬

W sin sin Y w ¬y sin 68° sin 7 1° w ¬ 7.4

sin70° ¬3.2sin52° 3.2 si n 52° ¬ sin 70°

7.4sin68° ¬wsin71° 7.4 si n 68° sin 71° ¬w

¬2.7

7.3 ¬w

219

Chapter 7

Y sin sin X y ¬x sin 9 6° sin X 23.7 ¬ 10.3

23.

W sin sin X w ¬x sin 3 8° sin27° 8.5 ¬ x

10.3sin96° ¬23.7sinX

xsin38° ¬8.5sin27°

10.3 si n 96° ¬sinX 23.7 10.3 s i n 96° ¬X 23.7

sin1

8.5 si n 27° x ¬ sin 38° x ¬6.3

W sin sin Y w ¬y sin 3 8° sin1 15° y 8.5 ¬

25.6° ¬X

mW mX mY ¬180 mW 25.6 96 ¬180 mW 121.6 ¬180 mW ¬58.4

ysin38° ¬8.5sin115° 8.5 sin 115° y ¬ sin 38°

y ¬12.5

W sin sin Y w ¬y sin5 8.4° sin 9 6° ¬ w 23.7

27. mW mX mY ¬180 36 mX 62 ¬180 mX 98 ¬180 mX ¬82

23.7sin58.4° ¬wsin96° 23.7 sin 58.4° ¬w sin 96°

W sin sin X w ¬x sin 3 6° sin 82° 3.1 ¬ x

20.3 ¬w 24. mW mX mY ¬180 52 25 mY ¬180 77 mY ¬180 mY ¬103

xsin36° ¬3.1sin82° 3.1 si n 82° x ¬ sin 36° x ¬5.2

W sin sin Y w ¬y sin 52° sin 1 03° w ¬ 15.6

W sin sin Y w ¬y sin 3 6° sin 62° 3.1 ¬ y

15.6 sin52° ¬wsin103° 15.6 si n 52° sin 103° ¬w

ysin36° ¬3.1sin62°

12.6 ¬w

3.1 si n 62° y ¬ sin 36° y ¬4.7


W sin sin Y w ¬y sin 1 07° sin Y ¬ 30 9.5

28.

15.6sin25° ¬x sin103°

9.5sin107° ¬30sinY

15.6 si n 25° sin 103° ¬x

9.5sin 107° ¬sinY 30 9.5si n 107° ¬Y 30

6.8 ¬x 25.

sin1

X sin sin Y x ¬y sin X sin 1 12° 20 ¬ 56

17.6° ¬Y

mW mX mY ¬180 107 mX 17.6 ¬180 mX 124.6 ¬180 mX ¬55.4

56sinX ¬20sin112° 20sin 112° sinX ¬ 56 20sin 112° X ¬sin1 56

W X sin sin w ¬ x sin 1 07° sin5 5.4° ¬ x 30

X ¬19.3°

mW mX mY ¬180 mW 19.3 112 ¬180 mW 131.3 ¬180 mW ¬48.7

xsin107° ¬30sin55.4° 30 sin 55.4° x ¬ sin 107°

x ¬25.8

W sin sin Y w ¬y sin4 8.7° sin 1 12° ¬ w 56

W X sin sin w ¬ x sin 8 8° sin X 21 ¬ 16

29.

56sin48.7° ¬wsin112° 56 sin 48.7° sin 112° ¬w

16sin88° ¬21sinX 16sin 88° ¬sinX 21 16s in 88° ¬X 21

45.4 ¬w

sin1

26. mW mX mY ¬180 38 mX 115 ¬180 mX 153 ¬180 mX ¬27 Chapter 7

220

49.6° ¬X

mW mX mY ¬180 88 49.6 mY ¬180 137.6 mY ¬180 mY ¬42.4

33.

b

W sin sin Y w ¬y sin 8 8° sin4 2.4° y 21 ¬

A

a

43

48

B

20 mi

mA mB mP ¬180 43 48 mP ¬180 91 mP ¬180 mP ¬89

y sin88° ¬21sin42.4° 21 sin 42.4° y ¬ sin 88°

y ¬14.2 30. Let x be the measure of each base angle. x x 44 ¬180 2x 44 ¬180 2x ¬136 x ¬68 Let y be the measure of each of the congruent sides.

A sin P sin 20 ¬ a sin 8 9° sin 43° 20 ¬ a

asin89° ¬20sin43°. 20 sin 43° a ¬ sin 89° a ¬13.6 B sin P sin 20 ¬ b sin 8 9° sin 48° 20 ¬ b

sin 4 4° sin 68° 46 ¬ y

y sin44° ¬46sin68°

bsin89° ¬20sin48°

46 sin 68° y ¬¬ sin 44° y ¬61.4 The perimeter of the triangle is about 46 61.4 61.4 or 168.8 cm.

20 sin 48° b ¬ sin 89° b ¬14.9 The first station is about 14.9 miles from the plane, and the second station is about 13.6 miles from the plane.

sin 2 8° sin 4 0° 12 ¬ AB

31.

P

34.

ABsin28° ¬12sin40°

T

12 sin 40° AB ¬ sin28°

AB ¬16.43

AB DC and AD BC, so the perimeter of ABCD is 2(16.43) 2(12) or 56.9 units. 32.

Z b

a

d

y

x

78

44

80

A

X 26 ft Y mX mY mZ ¬180 44 78 mZ ¬180 122 mZ ¬180 mZ ¬58

85

315 ft

B

mA mB mT ¬180 80 85 mT ¬180 165 mT ¬180 mT ¬15

sin 44° sin 5 8° x ¬ 26

A sin T sin 315 ¬ a sin 1 5° sin 80° 315 ¬ a

26sin44° ¬xsin58° 26 sin 44° sin 58° ¬x

asin15° ¬315sin80°

21.3 ¬x

315 si n 80° a ¬ sin 15°

sin 78° sin 5 8° y ¬ 26

a ¬1198.6 B sin sin 90° d ¬a sin 90° sin 85° d ¬ 119 8.6

26sin78° ¬ysin58° 26 sin 78° sin 58° ¬y

30 ¬y The length of fence needed is about 30 21.3 26 or 77.3 feet.

1198.6sin85° ¬dsin90° 1198.6 sin 85° ¬d sin 90°

1194.0 ¬d

The distance across the gorge is about 1194 feet.

221

Chapter 7

35. The plot of land is an isosceles triangle. Let x represent the measure of one of the base angles. x x 85 ¬180 2x 85 ¬180 2x ¬95 x ¬47.5 Let y represent the length of the base of the triangle.

39. See art for Exercise 38. B sin sin C b ¬ 60 sin1 24° sin 2 9° ¬ b 60

60sin124° ¬bsin29° 60 sin 124° sin 29° ¬b

102.6 ¬b 60 a 60 56.2 or 116.2 116.2 102.6 13.6 Keisha added about 13.6 miles to the flight.

sin 4 7.5° sin 85° ¬ y 160

y sin47.5° ¬160sin85°

A C sin sin 40. Yes; in right ABC, a c where C is the

160 si n85° y ¬ sin 47.5°

asi nC right angle. Then sinA c . Since mC ¬90,

y ¬216 The perimeter of the property is about 160 160 216 or 536 feet, so 536 feet of fencing material is needed. 36.

asin 90° then sinA . Since sin90° 1, then c

sinA ac, which is the definition of the sine ratio. 41. Sample answer: Triangles are used to determine distances in space. Answers should include the following. • The VLA is one of the world’s premier astronomical radio observatories. It is used to make pictures from the radio waves emitted by astronomical objects. • Triangles are used in the construction of the antennas.

P k

j

27

40

K

J

1433 m

mK mJ mP ¬180 40 27 mP ¬180 67 mP ¬180 mP ¬113

42. mX mY mZ ¬180 48 112 mZ ¬180 160 mZ ¬180 mZ ¬20

sin J P sin 1433 ¬ j sin 1 13° sin 27° 1433 ¬ j

jsin113° ¬1433sin27°

X sin sin Y x ¬y sin 4 8° sin1 12° y 12 ¬

1433s in 27° j ¬ sin 113°

j ¬706.8 Kayla and Paige are about 706.8 meters apart.

ysin48° ¬12sin112° 12 sin 112° y ¬ sin 48°

37. See art for Exercise 36.

y ¬15.0

sin P sin K 143 3 ¬k sin 1 13° sin 40° 1433 ¬ k

X sin sin Z x ¬z sin 4 8° sin 20° 12 ¬ z

ksin113° ¬1433sin40°

zsin48° ¬12sin20°

1433s in 40° k ¬ sin 113°

12 sin 20° z ¬ sin 48°

k ¬1000.7 Jenna and Paige are about 1000.7 meters apart. 38.

b

C

z ¬5.5

77 9 8 31 43. A; Metropolis Grill: 4 4 7.75 10 8 35 2 6 Le Circus: 4 4 6.5

A 27

a 124

46 8 9 27 Aquavent: 4 4 6.75

47 7 9 2 7 Del Blanco’s: 4 4 6.75

60 mi

Metropolis Grill has the best average rating of the four restaurant choices.

B mA mB mC ¬180 27 124 mC ¬180 151 mC ¬180 mC ¬29

Page 383 Maintain Your Skills 44. Find x so that the angle of elevation is 73.5°.

A sin sin C a ¬ 60 sin 27° sin 2 9° a ¬ 60

6 1 tan73.5° ¬ x xtan73.5° ¬7

60sin27° ¬asin29°

7 x ¬ tan7 3.5° x ¬2.07 The overhang should be about 2.07 feet long.

60 sin 27° sin 29° ¬a

56.2 ¬a Keisha must fly about 56.2 miles. Chapter 7

222

2 b2 2 82 c2 a 102 7 53. ¬ 2ab 2(7)(8)

45. Let y represent the amount of the window that will get direct sunlight.

9 64 100 4 ¬ 112

7y tan26.5° ¬ 2.07 2.07tan26.5° ¬7 y

13 ¬ 1 12 ¬ 112 13

2 b2 2 92 c2 a 62 4 54. ¬ 2(4)(9) 2ab

y ¬7 2.07tan26.5° y ¬5.97 About 5.97 feet of the window will get direct sunlight.

36 16 81 ¬ 72 6 1 6 1 ¬ 72 ¬ 72

j k 8 sinJ 17

cosJ k

tanJ

15 cosJ 17

8 tanJ 15

sinJ 0.47

cos J 0.88

tan J 0.53

sinL k 15 sinL 17

j cosL k 8 cosL 17

tanL j

sinL 0.88

cos L 0.47

tanL 1.88

j k 20 sinJ 29

cosJ k

tanJ

21 cosJ 29

j 20 tanJ 21

sinJ 0.69

cos J 0.72

tan J 0.95

sinL k 21 sinL 29

j cosL k 20 cosL 29

tanL j 21 tanL 20

sinL 0.72

cos L 0.69

tanL 1.05

j k 12 sinJ 24 sinJ 1 2

cosJ k

tanJ

3 12 cosJ 24

12 tanJ

3 cosJ 2

12 3 3 tanJ 3

sinJ 0.50

cos J 0.87

tan J 0.58

16 1. tanx° ¬ 10 16 x ¬tan1 10

sinL k 3 12 sinL 24 3 sinL 2

j cosL k 12 cosL 24 cosL 1 2

tanL j

2.

x cos17° ¬ 9.7 9.7cos17° ¬x 9.3 ¬x

sinL 0.87

cos L 0.50

tanL 1.73

3.

j k 2 7 sinJ 14 2 sinJ 2

cosJ k

tanJ

32 cos53° ¬ x xcos53° ¬32

2 7 cosJ 14 2 cosJ 2

7 2 tanJ 2 7

sinJ 0.71

cos J 0.71

sinL k

cosL

46. sinJ

47. sinJ

48. sinJ

49. sinJ

2 7 sinL 14 2 sinL 2

j k 2 7 cosL 14 2 cosL 2

j

2 b2 2 82 c2 a 102 5 55. ¬ 2(5)(8) 2ab

100 2 5 64 1 1 ¬ ¬ 80 80 2 b2 62 42 c2 a 132 1 56. ¬ 2(16)(4) 2ab

169 25 6 16 ¬ 128

1 5 tanL 8

1 03 10 3 ¬ 128 ¬ 128

2 b2 c2 a 92 32 102 57. ¬ 2(3)(10) 2ab

81 9 100 ¬ 60 2 8 7 ¬ 60 ¬ 15

2 b2 2 72 c2 a 112 5 58. ¬ 2(5)(7) 2ab

121 2 5 49 47 ¬ ¬ 70 70

j


x ¬58.0

3 12 tanL 12

tanL 3 j

32 x ¬ cos 5 3°

x ¬53.2

tanJ 1.00

4.

5m

tanL j

7 2 tanL

15

72

15

tanL 1.00

cos L 0.71 sinL 0.71 50. m1 54 120 Exterior Angle Theorem m1 66 51. m2 54 alternate interior 52. m2 m3 36 ¬180 Angle Sum Theorem 54 m3 36 ¬180 m3 90 ¬180 m3 ¬90

500 m

x

x

x tan15° ¬ 500 5

495tan15° ¬x 132.6 ¬x The distance is about 132.6 meters.

223

Chapter 7

D F sin sin EF ¬ DE sin D sin 8 2° 8 ¬ 12

5.

5. a2 ¬b2 c2 2bccosA a2 ¬1072 942 2(107)(94)cos105° a2 ¬20,285 20,116 cos105° a ¬20,28 5 ,116 20os105 c° a ¬159.7 6. s2 ¬r2 t2 2rtcosS 652 ¬332 562 2(33)(56)cos S 4225 ¬4225 3696 cosS 0 ¬3696 cosS 0 ¬cosS S ¬cos1(0) S ¬90° 7. r2 ¬s2 t2 2stcosR 2.22 ¬1.32 1.62 2(1.3)(1.6)cos R 4.84 ¬4.25 4.16 cosR 0.59 ¬4.16 cosR

12sinD ¬8sin82° 8sin 82° sinD ¬ 12 8sin 82° D ¬sin1 12

D ¬41° mD mE mF ¬180 41 mE 82 ¬180 mE 123 ¬180 mE ¬57 E D sin sin DF ¬ EF sin5 7° sin 41° D F ¬8

8sin57° ¬DF sin41°

0.5 9 4.16 ¬cosR

8 sin 57° sin 41° ¬DF

10.2 ¬DF

0.5 9 R ¬cos1 4.16

R ¬98° 8. We know the measures of three sides (SSS), so use the Law of Cosines. x2 ¬y2 z2 2yzcosX 52 ¬102 132 2(10)(13)cos X 25 ¬269 260 cosX 244 ¬260 cosX

Page 384 Geometry Software Investigation: The Ambiguous Case of the Law of Sines 1. BD, AB, and mA 2. Sample answer: There are two different triangles. 3. Sample answer: The results are the same. In each case, two triangles are possible. 4. Sample answer: Circle B intersects AC at only one point. See students’ work. 5. Yes; sample answer: There is no solution if circle B does not intersect AC.

2 44 260 ¬cosX

2 44 X ¬cos1 260

X ¬20°

X sin sin Y x ¬y sin 20° sin Y ¬ 5 10

10sin20° ¬5sinY 10sin20° ¬sinY 5 10si n20° ¬Y 5

The Law of Cosines

7-7

sin1

Pages 387–388 Check for Understanding 1. Sample answer: Use the Law of Cosines when you have all three sides given (SSS) or two sides and the included angle (SAS). Y R 6

Q

8 12

S

X

10 38

15

Z

2. If you have all three sides (SSS) or two sides and the included angle (SAS) given, then use the Law of Cosines. If two angles and one side (ASA or AAS) or two sides with angle opposite one of the sides (SSA) are given, then use the Law of Sines. 3. If two angles and one side are given, then the Law of Cosines cannot be used. 4. b2 ¬a2 c2 2accosB b2 ¬52 (2 )2 2(5)(2 )cos45° 2 b ¬27 102 cos45° b ¬ 27 1 02 c os45° b ¬4.1

Chapter 7

43° ¬Y mX mY mZ ¬180 20 43 mZ ¬180 mZ ¬117 9. We know the measures of two sides and the included angle (SAS), so use the Law of Cosines. 2 ¬k2 m2 2kmcosL 2 ¬202 242 2(20)(24)cos47° 2 ¬976 960 cos47° ¬976 os47° 960 c ¬17.9 sin L sin K ¬k sin 4 7° sin K 17.9 ¬ 20

20sin47° ¬17.9sin K 20 sin 47° ¬sinK 17.9 20 si n 47° ¬K 17.9

sin1

55° ¬K mK mL mM ¬180 55 47 mM ¬180 mM ¬78

224

10. Let n, d, and q be the measures of the sides opposite N, D, and Q, respectively.

16.

1 n 1 2 (10) 2 (24) or 17 mm 1 d 1 2 (24) 2 (22) or 23 mm

e2 ¬f2 g2 2fgcosE 142 ¬192 322 2(19)(32)cos E 196 ¬1385 1216cos E 1189 ¬1216cos E 11 89 1216 ¬cosE

1 q 1 2 (10) 2 (22) or 16 mm

118 9 E ¬cos1 1216

n2 ¬d2 q2 2dqcosN 172 ¬232 162 2(23)(16)cos N 289 ¬785 736cos N 496 ¬736cos N

E ¬12° 17. f 2 ¬e2 g2 2egcosF 1982 ¬3252 2082 2(325)(208)cos F 39,204 ¬148,889 135,200cos F 109,685 ¬135,200cos F

4 96 736 ¬cosN

4 96 N ¬cos1 736 N ¬47.6° q2 ¬n2 d2 2ndcosQ 162 ¬172 232 2(17)(23)cos Q 256 ¬818 782 cosQ 562 ¬782 cosQ

109,685 ¬cosF 135 ,200

109,685 F ¬cos1 135, 200

18.

5 62 782 ¬cosQ

5 62 Q ¬cos1 782

F ¬36° g2 ¬e2 f 2 2efcosG 102 ¬21.92 18.92 2(21.9)(18.9)cos G 100 ¬836.82 827.82cosG 736.82 ¬827.82cosG 736 .82 827.82 ¬cosG

Q ¬44.1° mQ mD mN ¬180 44.1 mD 47.6 ¬180 mD ¬88.3

736 .82 G ¬cos1 827.82

G ¬27°

H sin sin F h ¬0f sin H sin 4 0° 8 ¬ 10

19.


10sinH ¬8sin40°

11. u2 ¬t2 v2 2tvcosU u2 ¬9.12 8.32 2(9.1)(8.3)cos32° u2 ¬151.7 151.06 cos32° u ¬151.7 .06 151s32° co u ¬4.9 12. v2 ¬t2 u2 2tucosV v2 ¬112 172 2(11)(17)cos78° v2 ¬410 374 cos78° v ¬410 os78° 374 c v ¬18.2 13. t2 uu2 v2 2uvcosT t2 ¬112 172 2(11)(17)cos105° t2 ¬410 374 cos105° t ¬410 os105 374 c° t ¬22.5 14. t2 uu2 v2 2uvcosT t2 ¬172 112 2(17)(11)cos59° t2 ¬410 374 cos59° t ¬410 os59° 374 c t ¬14.7 15. f 2 ¬e2 g2 2egcosF 8.32 ¬9.12 16.72 2(9.1)(16.7)cosF 68.89 ¬361.7 303.94 cosF 292.81 ¬303.94 cos F

8sin 40° sinH ¬ 10 8sin 40° H ¬sin1¬ 10

H ¬31°

mF mG mH ¬180 40 mG 31 ¬180 mG ¬109 G F sin sin g ¬0 f sin1 09° sin 4 0° ¬ g 10

10sin109° ¬gsin40° 10 sin 109° sin 40° ¬g

14.7 ¬g 20. um2 q2 2mqcosP p2 ¬112 102 2(11)(10)cos38° p2 ¬221 220 cos38° p ¬221 os38° 220 c p ¬6.9 p2

P sinM sin m ¬0 p sin M sin 3 8° 11 ¬ 6.9

6.9sin M ¬11sin38°

292 .81 303.94 ¬cosF

11sin 38° sinM ¬ 6.9 11sin 38° M ¬sin1 6.9

292 .81 F ¬cos1 303.94

M ¬79°

F ¬16°

mM mP mQ ¬180 79 38 mQ ¬180 mQ ¬63

225

Chapter 7

21.

A sin sin B a ¬b sin 3 0° sin B 15 ¬ 19

b2 ¬c2 d2 2cdcosB 182 ¬152 112 2(15)(11)cos B 324 ¬346 330cos B 22 ¬330cos B 2 2 330 ¬cosB

19sin30° ¬15sinB 19sin 30° ¬sinB 15 19s in 30° ¬B 15

2 2 B ¬cos1 330

sin1

B ¬86°

B C sin sin b ¬0 c sin 8 6° sin C 18 ¬ 15

15sin86° ¬18sinC

25.

15sin 86° ¬sinC 18 15sin 86° ¬C 18

sin1

14.9 si n 53° sin 28° ¬a

25.3 ¬a mA mB mC ¬180 53 mB 28 ¬180 mB ¬99

A C sin sin a ¬ c sin 42° sin 77° a ¬6

sin C B sin b ¬c sin 99° sin 2 8° b ¬ 14.9

6sin42° ¬asin77° 6 sin 42° sin 77° ¬a

14.9 sin 99° ¬b sin 28° 14.9 si n 99° sin 28° ¬b

4.1 ¬a mA mB mC ¬180 42 mB 77 ¬180 mB ¬61

31.3 ¬b 26. Find mDAB and mBCD. DB2 ¬AB2 AD2 2(AB)(AD)cos(DAB)

B C sin sin b ¬ c sin 61° sin 77° b ¬6

2

723

6 sin 61° sin 77° ¬b

5.4 ¬b 23. c2 ¬a2 b2 2abcosC c2 ¬10.32 9.52 2(10.3)(9.5)cos37° c2 ¬196.34 195.7cos37° c ¬ 196.3 4 19 5.7cos 37° c ¬6.3

2

723

¬82 82 2(8)(8)cos(BCD)

52 9 9 ¬128 128cos(BCD) 6 23 9 ¬128cos(BCD) 1 3 62 128 9 ¬cos(BCD) 1 62 3 mBCD ¬cos1 128 9

6.3sin A ¬10.3sin37° 10.3 si n37° sinA ¬ 6.3

10.3 si n37° A ¬sin1 6.3

A ¬80° mA mB mC ¬180 80 mB 37 ¬180 mB ¬63 24. a2 ¬b2 c2 2bccosA 152 ¬192 282 2(19)(28)cos A 225 ¬1145 1064cos A 920 ¬1064cos A

mBCD ¬57 sin L sinM ¬m sin 2 3° sin M 54 ¬ 44

27.

44sin23° ¬54sinM 44sin 23° ¬sinM 54 44s in 23° ¬M 54

sin1

18.6° ¬M

92 0 1064

A ¬30° Chapter 7

mDAB ¬100 BD2 ¬BC2 DC2 2(BC)(DC)cos(BCD)

A C sin sin a ¬ c sin A sin 3 7° 10.3 ¬ 6.3

A ¬cos1

¬52 52 2(5)(5)cos(DAB)

52 9 9 ¬50 50cos(DAB) 7 9 9 ¬50cos(DAB) 1 79 5 0 9 ¬cos(DAB) 1 79 mDAB ¬cos1 5 0 9

6sin61° ¬bsin77°

9 20 1064 ¬cosA

A sin sin C a ¬c sin sin 2 8° a53° ¬ 14.9

14.9sin53° ¬asin28°

56° ¬C mB mC mD ¬180 86 56 mD ¬180 mD ¬38 22.

39° ¬B mA mB mC ¬180 30 39 mC ¬180 mC ¬111

226

sinM sin N m ¬n sin 46° sin 7 9° m ¬ 16

mL mM mN ¬180 23 18.6 mN ¬180 mN ¬138.4

16sin46° ¬msin79°

N sin sin L n ¬ sin138.4° sin 2 3° n ¬ 54

16 sin 46° sin 79° ¬m

54sin138.4° ¬nsin23°

31.

54sin 1 38.4° ¬n sin 23°

91.8 ¬n 28. ¬2 n2 2ncosM 2 18 ¬242 302 2(24)(30)cos M 324 ¬1476 1440cos M 1152 ¬1440cos M m2

11.7 ¬m 2 ¬m2 n2 2mncosL 4232 ¬2562 2882 2(256)(288)cosL 178,929 ¬148,480 147,456cos L 30,449 ¬147,456cos L

30,449 147 ,456 ¬cosL

L ¬cos1 147 ,456

L ¬101.9°

11 52 1440 cosM

M ¬cos1

sin L sinM ¬m sin 10 1.9° sin M ¬ 423 256

115 2 1440

M ¬36.9°

256sin101.9° ¬423sin M

sinM sin L m ¬ sin 3 6.9° sin L ¬ 18 24

256sin 101.9° ¬sinM 423 256si n 1 01.9° ¬M 423

sin1

24sin36.9° ¬18sinL

53.2° ¬L mL mM mN ¬180 53.2 36.9 mN ¬180 mN ¬89.9 29. 2 ¬m2 n2 2mncosL 2 ¬192 282 2(19)(28)cos49° 2 ¬1145 1064cos49° ¬ 1145 1064 cos49° ¬21.1

32. m2 ¬2 n2 2ncosM m2 ¬6.32 6.72 2(6.3)(6.7)cos55° m2 ¬84.58 84.42cos55° m ¬ 84.58 84. 42cos 55° m ¬6.0 sinM sin L m ¬ sin 55° sin L ¬ 6 6.3

6.3sin55° ¬6sinL

sin L sinM ¬m sin 4 9° sin M 21.1 ¬ 19

6.3si n55° ¬sinL 6 6.3si n55° ¬L 6

sin1

19sin49° ¬21.1sin M

59.3° ¬L mL mM mN ¬180 59.3 55 mN ¬180 mN ¬65.7 33. m2 ¬2 n2 2ncosM m2 ¬52 102 2(5)(10)cos27° m2 ¬125 100cos27° m ¬ 125 100co s27° m ¬6.0

19 sin 49° 21.1 ¬sinM 19 sin 49° ¬M 21.1

sin1

36.3° ¬M mL mM mN ¬180 101.9 36.3 mN ¬180 mN ¬41.8

24sin 36.9° ¬sinL 18 24si n 36.9° ¬L 18

sin1

30,449

42.8° ¬M mL mM mN ¬180 49 42.8 mN ¬180 mN ¬88.2 30. mL mM mN ¬180 55 46 mN ¬180 mN ¬79

sin L sinM ¬m sin L sin 27° 5 ¬ 6

sin L sin N ¬n sin 55° sin 7 9° ¬ 16

6sinL ¬5sin27° 5sin 27° sinL ¬ 6

16sin55° ¬ sin79°

5sin 27° L ¬sin1 6

16 sin 55° sin 79° ¬

13.4 ¬

L ¬22.2° mL mM mN ¬180 22.2 27 mN ¬180 mN ¬130.8

227

Chapter 7

34.

2 ¬m2 n2 2mncosL 142 ¬202 172 2(20)(17)cos L 196 ¬689 680cos L 493 ¬680cos L

sin L sin N ¬n sin 5 1° sin N 40 ¬ 35

37.

35sin51° ¬40sinN

4 93 680 ¬cosL

35sin 51° ¬sinN 40 35s in 51° ¬N 40

49 3 L ¬cos1 680

sin1

L ¬43.5°

42.8° ¬N mL mM mN ¬180 51 mM 42.8 ¬180 mM ¬86.2

sin L sinM ¬ m sin 4 3.5° si n M ¬ 14 20

sin L sinM ¬m sin 5 1° sin 86.2° m 40 ¬

20sin43.5° ¬14sinM 20sin 43.5° ¬sinM 14 20si n 43.5° ¬M 14

sin1

msin51° ¬40sin86.2° 40 sin 86.2° m ¬ sin 51°

79.5° ¬M mL mM mN ¬180 43.5 79.5 mN ¬180 mN ¬57.0 35. m2 ¬2 n2 2ncosM m2 ¬142 212 2(14)(21)cos60° m2 ¬637 588cos60° m ¬ 637 588co s60° m ¬18.5

38.

m ¬51.4 2 ¬m2 n2 2mncosL 102 ¬112 122 2(11)(12)cos L 100 ¬265 264cos L 165 ¬264cos L 1 65 264 ¬cosL

16 5 L ¬cos1 264

sin L sinM ¬m sin L sin 6 0° 14 ¬ 18.5

L ¬51.3° sin L sinM ¬m sin 51.3° sin M ¬ 11 10

18.5sinL ¬14sin60° 14 sin 60° sinL ¬ 18.5

L

¬sin1

14 sin 60° 18.5

11sin51.3° ¬10sinM 11sin 51.3° ¬sinM 10 11sin 51.3° ¬M 10

sin1

L ¬40.9° mL mM mN ¬180 40.9 60 mN ¬180 mN ¬79.1 36. 2 ¬m2 n2 2mncosL 142 ¬152 162 2(15)(16)cos L 196 ¬481 480cos L 285 ¬480cos L

59.1° ¬M mL mM mN ¬180 51.3 59.1 mN ¬180 mN ¬69.6 39. BC2 ¬BP2 PC2 2(BP)(PC)cos(BPC) 2

2

1 BC2 ¬1 2 214 2 188

2 85 480 ¬cosL

1 21 2 214 2 188 cos70°

28 5 L ¬cos1 480

BC2 ¬20,285 20,116 cos70° BC ¬20,28 5 ,116 20os70° c BC ¬115.8 AB2 ¬AP2 BP2 2(AP)(BP)cos(APB)

L ¬53.6° sin L sinM ¬ m sin 5 3.6° sin M ¬ 14 15

2

2

1 AB2 ¬1 2 188 2 214

15sin53.6° ¬14sinM

1 21 2 188 2 214 cos(180 70)°

15sin 53.6° ¬sinM 14 15sin 53.6° ¬M 14

sin1

AB2 ¬20,285 20,116 cos110°

AB ¬20,28 5 ,116 20os110 c° AB ¬164.8 AB DC and AD BC, so the perimeter of ABCD is 2(115.8) 2(164.8) or 561.2 units. 40. QS2 ¬PQ2 PS2 2(PQ)(PS)cosP QS2 ¬7212 7562 2(721)(756)cos58° QS2 ¬1,091,377 1,090,152cos58°

59.6° ¬M mL mM mN ¬180 53.6 59.6 mN ¬180 mN ¬66.8

QS ¬1,091 ,377 ,152 1,090os58° c QS ¬716.7 Chapter 7

228

sin(PQS) ¬sin P ¬ PS Q S sin(PQS) ¬sin 58° 5 ¬ 716 .7 7 6

242 ¬302 222 2(30)(22)cos A 576 ¬1384 1320cos A 808 ¬1320cos A

716.7 sin(PQS) ¬756sin58°

8 08 1320 ¬cosA

756 sin 58°

sin(PQS) ¬ 716 .7

80 8 A ¬cos1 1320

756 si n 58° mPQS ¬sin1 716.7

A ¬52.3° Adam has a greater angle, which is 52.3°. 43a. Pythagorean Theorem 43b. Substitution 43c. Pythagorean Theorem 43d. Substitution 43e. Def. of cosine 43f. Cross products 43g. Substitution 43h. Commutative Property

mPQS ¬63.5 QS2 ¬QR2 RS2 2(QR)(RS)cos R 716.72 ¬5472 5932 2(547)(593)cosR 513,658.89 ¬650,858 648,742 cos R 137,199.11 ¬648,742 cos R 137,199.11 ¬cosR 648,742 R ¬cos1 648,742 137,199.11

R ¬77.8° 41.

A

174 ft

C

44. AB [10 (6)]2 [ 4 ( 8)]2 162 42 272 BC (6 1 0)2 [8 (4)] 2 2 2 (4) 12 160 AC [6 ( 6)]2 [8 (8)]2 2 2 12 16 400 or 20 AC2 ¬BC2 AB2 2(BC)(AB)cos B

180 ft

B

186 ft

a2 ¬b2 c2 2bccosA 1862 ¬1742 1802 2(174)(180)cosA 34,596 ¬62,676 62,640cos A 28,080 ¬62,640 cos A

2

¬2160 272 cosB

28,080 ¬cosA 62,640

400 ¬432 243,52 0 cosB

A ¬cos1 62,640 28,080

32 ¬243,52 0 cosB

A ¬63.4°

2 3 ¬cosB 2 43,52 0

A sin sin B a ¬b sin 6 3.4° sin B ¬ 186 174

2 43,520

32 B ¬cos1

B ¬85.6° So, mABC 85.6°. CB2 ¬AB2 AC2 2(AB)(AC)cos A

174sin63.4° ¬186sin B 174sin 63.4° ¬sinB 186 174sin 63.4° ¬B 186

sin1

2

202 ¬160 272

2

160

56.8° ¬B mA mB mC ¬180 63.4 56.8 mC ¬180 mC ¬59.8 42. Let C represent Carlos’s angle and A represent Adam’s angle. 242 ¬402 502 2(40)(50)cos C 576 ¬4100 4000cos C 3524 ¬4000cos C

2

¬272 202 2272 (20)cosA

160 ¬672 40272 cosA 512 ¬40272 cosA 5 12 ¬cosA 40 272

402 72

51 2 A ¬cos1

A ¬39.1° mDCA mB mA 85.6 39.1 or 124.7 45. Sample answer: Triangles are used to build supports, walls, and foundations. Answers should include the following. • The triangular building was more efficient with the cells around the edge. • The Law of Sines requires two angles and a side or two sides and an angle opposite one of those sides.

35 24 4000 ¬cosC

352 4 C ¬cos1 4000

C ¬28.2°

229

Chapter 7

46. B; d2 ¬e2 f 2 2efcosD d2 ¬122 152 2(12)(15)cos75° d2 ¬369 360cos75° d ¬ 369 360co s75° d ¬16.6 47. C; earnings base salary commission Let s represent her sales for the month. 4455 ¬1280 0.125s 3175 ¬0.125s 25,400 ¬s Her sales that month were $25,400.

53. To show that A B

C D , we must show that AB AE . CD CE A B AE 8 or 2, and 9. Since the side lengths CD CE 4 4

B is not parallel to C D . are not proportional, A 54. To show that A B

C D , we must show that AB BE CD D E. A B BE 5 .4 18 or 9, and 9 CD D E 3 5 10 or 5 . AB BE Thus, CD D E . Since the sides have proportional

B

C D . lengths, A 55. Given: JFM EFB LFM GFB Prove: JFL EFG H G L J E F


X Y sin sin x ¬ y sin 22° sin 4 9° ¬ x 4.7

4.7sin22° ¬x sin49° 4.7 sin 22° ¬x sin 49°

2.3 ¬x

D

X Y sin sin x ¬ y sin 5 0° sin Y 14 ¬ 10

49.

10sin 50° ¬sinY 14 10sin 50° ¬Y 1 4

JF LF M F M F E F BF and BF GF . By the Transitive JF LF Property of Equality, E F G F . F F by the

33° ¬Y

Reflexive Property of Congruence. Then, by SAS Similarity, JFL EFG. 56. Given: J M E B M L G B Prove: J L

E G H G L J E F

50. x 23

1.55 m 100 m

x tan23° ¬ 100

100tan23° ¬x 42.45 ¬x x 1.55 ¬42.45 1.55 or 44.0 The height of the building is about 44.0 meters. 51. To show that A B

C D , we must show that

D

M

C

A B Proof: Since J M

E B and L M

G B , then MJF BEF and FML FBG because if two parallel lines are cut by a transversal, corresponding angles are congruent. EFB EFB and BFG BFG by the Reflexive Property of Congruence. Then EFB JFM and FBG FML by AA JF LF M F M F Similarity. Then E F BF , BF GF by the

AC BD CE DE . AC 8 .4 BD 6. 3 or 7, and CE 6 5 DE 4.5 AC BD or 7 5 . Thus, CE DE . Since the sides have

B

C D . proportional lengths, A

JF LF definition of similar triangles. E F G F by the Transitive Porperty of Equality and EFG EFG by the Reflexive Property of Congruence. Thus, JFL EFG by SAS Similarity and FJL FEG by the definition of similar triangles. J L

E G because if two lines are cut by a transversal so that the corresponding angles are congruent, then the lines are parallel.

52. To show that A B

C D , we must show that AC BD C E DE .

CE AE AC 15 7 or 8. AC 7 So, C E 8.

DE BE BD 22.5 10.5 or 12. AC BD 10 .5 BD 7 So, DE 12 or 8 . Thus, CE DE . Since the B

C D . sides have proportional lengths, A

Chapter 7

C

A B Proof: Since JFM EFB and LFM GFB, then by the definition of similar triangles,

10sin50° ¬14sinY sin1

M

230

57.

y 4 ¬4x 8 y ¬4x 12 Solve a system of equations to find the point of intersection of the medians. x 8 ¬4x 12 3x 8 ¬12 3x ¬4 x ¬4 3

y

Z(0 , 1 2 ) Y(4, 8 )

X(8 , 0 ) x

Replace x with 4 3 in one of the equations to find the y-coordinate.

Find an equation of the altitude from X to Y Z . 2 8 1 The slope of Y Z is 0 (4) or 1, so the slope of the altitude is 1. y y1 ¬m(x x1) y 0 ¬1(x 8) y ¬x 8 Find an equation of the altitude from Z to X Y . 80 or 2, so the slope of The slope of X Y is 3 4 8

y 4 3 8 2 0 y 3

2 0 The coordinates of the centroid are 4 3 , 3 or about (1.3, 6.7).

59.

y

Z(0 , 1 2 )

the altitude is 3 2.

y y1 ¬m(x x1)

Y(4 , 8 )

y 12 ¬3 2 (x 0) 3 y ¬2 x 12

X(8 , 0 ) x

Solve a system of equations to find the point of intersection of the altitudes.

x 8 ¬3 2 x 12

Find an equation of the perpendicular bisector of Y Z . 4 0 8 12 The midpoint of Y Z is or (2, 10). 2 , 2

8 ¬5 2 x 12 5 4 ¬2x 8 5 ¬x Replace x with 8 5 in one of the equations to find

the perpendicular bisector is 1. y y1 m(x x1) y 10 1[x (2)] y 10 x 2 y x 8 Find an equation of the perpendicular bisector of Y X . 8 (4) 0 8 , The midpoint of X Y is or (2, 4). 2 2

the y-coordinate. y 8 5 8

48 y 5

48 The coordinates of the orthocenter are 8 5 , 5 or (1.6, 9.6).

58.

8 12 Z is The slope of Y 0 (4) or 1, so the slope of

80 2 Y is The slope of X 4 8 or 3 , so the slope of 3 the perpendicular bisector is 2.

y

Z(0 , 1 2 )

y y1 m(x x1) y 4 3 2 (x 2)

Y(4, 8 )

y 3 2x 3 4 y 3 2x 1 Solve a system of equations to find the point of intersection of the perpendicular bisectors.

X(8 , 0 ) x Find an equation of the median from X to Y Z . 12 4 0 8 The midpoint of Y Z is , or (2, 10). 2 2

x 8¬ 3 2x 1

8¬ 5 2x 1

10 0 Then the slope of the median is 2 8 or 1.

7¬ 5 2x

y y1 ¬m(x x1) y 0 ¬1(x 8) y ¬x 8 Find an equation of the median from Z to X Y .

1 4 5 ¬ x

1 4 Replace x with 5 in one of the equations to find the y-coordinate. 1 4 y 5 8

8 8 (4) 0 , Y is or (2, 4). The midpoint of X 2 2 4 12 Then the slope of the median is 2 0 or 4.

2 6 y 5

1 4 26 The coordinates of the circumcenter are 5 , 5 or (2.8, 5.2).

y y1 ¬m(x x1) y 4 ¬4 (x 2)

231

Chapter 7

9. Let x represent the geometric mean. 4 x x 81 x2 324 x 324 x 18 10. Let x represent the geometric mean. 20 x x ¬ 35 x2¬ 700 x¬ 700 x¬ 26.5 11. Let x represent the geometric mean. 18 x x ¬ 44 x2¬ 792 x¬ 792 x¬ 28.1 12. Let x¬ RS.

Page 391 Geometry Activity: Trigonometric Identities 1. Sample answer: It is of the form a2 b2 c2, where c 1. 1 1 2. cos sec ; tan cot sin 3. cos tan

y

y r x r

y x

Original equation y

sin r, cos xr, tan yx

y

rxr x

Multiply by the reciprocal of xr.

y y x x cos 4. cot sin x x r y y r

Multiply. Original equation sin yr, cos xr, cot xy Multiply by the reciprocal of yr. Multiply.

x r x ry y x x y y

PS RS RS ¬ QS 8 x ¬ x 14

5. tan2 1 sec2 Original equation 2

y

x

2

y

1 xr

2 y2 1 r2 x x2 2 2 y2 x 2 1 (x2)xr2 x

y2 x2 r2 r2 r2 2 6. cot 1 csc2 2

x

y

2

1 yr

xy 1 yr y xy 1 (y )yr 2

2

2

2

2

2 2

2

x2 y2 r2 r2 r2

2

2

x2¬ 112 x¬ 112 or 47 x¬ 10.6 So RS¬ 10.6. 13. 152 202¬ x2 225 400¬ x2 625¬ x2 625 ¬ x 25¬ x

tan x, sec xr Evaluate exponents. Multiply each side by x2. Simplify. Substitution; y2 x2 r2 Original equation cot xy, sec yr

2

2

5 13 14. x2 1 7 ¬ 17 25 16 9 x2 28 9 ¬ 289

Evaluate exponents. Multiply each side by y2.

14 4 x2¬ 289

Simplify. Substitution; x2 y2 r2

x¬

14 4 289

12 x¬ 17

15. x2 132¬ 212 x2 169¬ 441 x2¬ 272 x¬ 272 or 417 x¬ 16.5 16. x 9 y 92 17. 13 x2 13 x

Chapter 7 Study Guide and Review Page 392 Vocabulary and Concept Check 1. 2. 3. 4. 5. 6. 7.

true false; opposite; adjacent false; a right true true false; 45°-45°-90° false; depression

2 13 2 x 2 2 132 2 x

yx

132 y 2

Pages 392–396 Lesson-by-Lesson Review 8. Let x represent the geometric mean. 4 x x 16 x2 64 x 64 x8

Chapter 7

18. x 2(6) or 12 y 63 19. z 183 a 2z a 2(183 ) or 363

232

14 z3

20.

26.

14 z 3 14 3 z 3 3 143 3 z

a 2z

B 60 ft

x

A

Let x represent mBAC. 60 tanx°¬ 500 3 60 tanx°¬ 1500

143 283 or a2 3 3

60 x¬ tan1 1500 x¬ 2.3 The angle of elevation must be greater than 2.3°.

z y3

143 3 y3 14 3 1 y 3 3 14 3 y

27.

D

A 100 ft

b 2y 14 28 b 2 3 or 3

x

C

21. sinF ac

12 4 15 or 5 0.80 tanF a b

10 0 tanx°¬ 240 10 0 x¬ tan1 240

9 or 3 12 4

x¬ 22.6 The angle of depression is about 22.6°.

0.75 sinG bc

28.

12 4 15 or 5 0.80 cosG ac

0.28 sinG bc

A

D

50 ft

x

C

9 3 1 5 or 5 0.60 b tanG ¬a

7 25

B

240 ft

Let x represent mABC. The ground and the horizontal level with the top of the escalator are parallel. Therefore, mDAB mABC since they are alternate interior angles.

9 3 1 5 or 5 0.60 cosF bc

1 2 4 ¬ 9 or 3 ¬1.33 22. sinF ac

C

500 yd

B

1000 ft

Let x represent mABC. The ground and the horizontal level with the initial point of the balloon are parallel. Therefore, mDAB mABC since they are alternate interior angles. cosF bc 24 25

0.96 cosG ac

24 25 0.96 23. sinP 0.4522 P sin1(0.4522) KEYSTROKES: 2nd mP 26.9 24. cosQ 0.1673 Q cos1(0.1673) KEYSTROKES: 2nd mQ 80.4 25. tanR 0.9324 R tan1(0.9324) KEYSTROKES: 2nd mR 43.0

7 2 5 0.28

50 tanx°¬ 1000

tanF¬¬a b 7 ¬ 24

50 x¬ tan1 1000

x¬ 2.9 The angle of depression is about 2.9°.

¬0.29 b tanG ¬a

29.

24 ¬ 7 ¬3.43

A

30 yd

[SIN1]

0.4522 ENTER 44

C

[COS1] 0.1673 ENTER

x

B

Let x represent the length of the shadow of the building, BC. 30 tan44°¬ x xtan44°¬ 30 30 x¬ tan 44° x¬ 31.1 The shadow is about 31.1 yards long.

[TAN1] 0.9324 ENTER

233

Chapter 7

30.

30 ft

x

400 ft

A

B

8.7sin29°¬ 4.8sin B

Let x represent mCAB. 3 0 tanx°¬ 400 3 0 x¬ tan1 400 x¬ 4.3 The angle of elevation of the track is about 4.3°.

F G sin sin f ¬ g sin 82° sin 4 8° f ¬ 16

C sin sin A c ¬ a sin 90° sin 2 9° c¬ 4.8

16 sin 82° sin 48° ¬ f

4.8sin90°¬ csin29° 4.8 si n 90° sin 29° ¬ c

21.3¬ f H G sin sin h ¬ g sin H sin 6 5° 10.5 ¬ 13

9.9¬ c 36. mA mB mC 180 29 64 mC 180 mC 87 A B sin sin ¬ a b

13sinH¬ 10.5sin65° 10.5 si n65° sinH¬ 13

sin 29° sin 6 4° a¬ 18.5

10.5 si n65° H¬ sin1 13

18.5sin29°¬ asin64°

H¬ 47°

18.5 si n 29° sin 64° ¬ a

A B sin sin a ¬ b sin 6 4° sin B 15 ¬ 11

33.

10.0¬ a B sin sin C b ¬ c si n 6 4° sin 87° ¬ c 18.5

11sin64°¬ 15sinB 11sin 64° ¬ sinB 15 11s in 64° ¬ B 15

csin64°¬ 18.5sin87°

sin1

18.5 si n 87° c¬ sin 64° c¬ 20.6 37. z2¬ x2 y2 2xycosZ z2¬ 7.62 5.42 2(7.6)(5.4)cos51° z2¬ 86.92 82.08cos51° z¬ 86.92 08cos 82.51° z¬ 5.9 38. y2¬ x2 z2 2xzcosY y2¬ 212 162 2(21)(16)cos73° y2¬ 697 672cos73° y¬ 697 s73° 672co y¬ 22.4 39. a2¬ b2 c2 2bccosA a2¬ 132 182 2(13)(18)cos64° a2¬ 493 468cos64° a¬ 493 s64° 468co a¬ 17.0 A sin sin B a ¬ b

41°¬ B mA mB mC 180 64 41 mC 180 mC 75 C A sin sin c¬ a sin 75° sin 6 4° c¬ 15

15sin75°¬ csin64° 15 sin 75° sin 64° ¬ c

16.1¬ c 34.

C A sin sin c ¬ a sin 6 7° sin 55° a 12 ¬

asin67°¬ 12sin55° 12 sin 55° a¬ sin 67°

a¬ 10.7 mA mB mC¬ 180 55 mB 67¬ 180 mB¬ 58 B C sin sin b ¬ c

sin 6 4° sin B 17 ¬ 13

13sin64°¬ 17sinB 13sin 64° ¬ sinB 17 13s in 64° ¬ B 17

sin 58° sin 6 7° b¬ 12

sin1

12sin58°¬ bsin67°

43°¬ B mA mB mC 180 64 43 mC 180 mC 73

12 sin 58° sin 67° ¬ b

11.1¬ b

Chapter 7

61°¬ B mA mB mC 180 29 61 mC 180 mC 90

16sin82°¬ fsin48°

32.

8.7si n 29° ¬ sinB 4.8 8.7s i n 29° ¬ B 4.8

sin1

31.

A sin sin B a ¬ b sin 2 9° sin B 4.8 ¬ 8.7

35.

C

234

B sin sin C b ¬ c sin B sin 5 3° 5.2 ¬ 6.7

40.

19 x 2 19 2 x 2 2 192 2 x

6.7sin B¬ 5.2sin53° 5.2si n 53° sinB¬ 6.7

5.2si n 53° B¬ sin1 6.7

yx

192 y 2

B¬ 38° mA mB mC¬ 180 mA 38 53¬ 180 mA¬ 89 A B sin sin a ¬ b

11. This is a 30°-60°-90° triangle with hypotenuse of length 12, shorter leg with length of y and longer leg with length of x. 12 2y 6y x y3 x 63 12. x2 82 162 x2 64 256 x2 192 x 192 x 83

sin 89° sin 3 8° a¬ 5.2

5.2sin89°¬ asin38° 5.2 si n 89° sin 38° ¬ a

8.4¬ a


8 siny° 1 6

8 y sin1 1 6 y 30

Page 397 1. 2abcosC 2. Yes; two perfect squares can be written as a a and b b. Multiplied together, we have a a b b. Taking the square root, we have ab, which is rational. 3. Sample answer: 2, 23 , 4 4. Let x represent the geometric mean. x 7 x 6 3 x2 441 x 441 or 21 5. Let x represent the geometric mean. x 6 x 2 4 2 x 144 x 144 or 12 6. Let x represent the geometric mean. 10 x x 5 0 x2 500 x 500 or 105 2 2 2 7. x 5 ¬ 6 x2 25¬ 36 x2¬ 11 x¬ 11 x¬ 3.32 8. 72 132¬ x2 49 169¬ x2 218¬ x2 218 ¬ x 14.8¬ x c2

a2

19 x2

10.

b2

BC 13. cosB AB 15 5 21 7 B C 14. tanA AC 15 16 BC 15. sinA AB 15 5 21 7

16.

F sin sin G f ¬ g sin 5 9° sin 71° g 13 ¬

gsin59°¬ 13sin71° 13 sin 71° g¬ sin 59° g¬ 14.3

17.

sin F sin H f¬ ¬h sin 5 2° sin H ¬ 10 12.5

12.5sin52° ¬10sinH 12.5 si n52° ¬sinH 10 12.5 si n52° ¬H sin1 10

80.1° ¬H 18. f 2¬ g2 h2 2ghcosF f 2¬ 152 132 2(15)(13)cos48° f 2¬ 394 390cos48° f¬ 394 s48° 390co f¬ 11.5 19. h2¬ f2 g2 2fgcosH h2¬ 13.72 16.82 2(13.7)(16.8)cos71° h2¬ 469.93 460.32cos71° h¬ 469.9 3 0.32co 46s71° h¬ 17.9

2

12 2 9. x2 2 ¬ 9 x2 36¬ 81 x2¬ 45 x¬ 45 x¬ 35 x¬ 6.7

235

Chapter 7

20. c2¬ a2 b2 2abcosC c2¬ 152 172 2(15)(17)cos45° c2¬ 514 510cos45° c¬ 514 s45° 510co c¬ 12.4 C A sin sin c ¬ a

since they are alternate interior angles. Let x represent CD, the horizontal distance to the city. 0.5 tan9°¬ x xtan9°¬ 0.5 0.5 x¬ tan 9°

sin 4 5° sin A 12.4 ¬ 15

x¬ 3.2 The horizontal distance to the city is about 3.2 miles.

15sin45°¬ 12.4sinA 15 sin 45° 12.4 ¬ sinA 15 sin 45° sin1 12.4 ¬ A

24.

59°¬ A mA mB mC¬ 180 59 mB 45¬ 180 mB¬ 76 21.

A

A B sin sin a ¬ b sin A sin 4 8° 12.2 ¬ 10.9 12.2 si n 48° sinA¬ 10.9 12.2 si n 48° A¬ sin1 10.9

A¬ 56° mA mB mC¬ 180 56 48 mC¬ 180 mC¬ 76 C sin sin B c ¬ b sin 76° sin 4 8° c¬ 10.9

10.9sin76°¬ csin48°

Chapter 7 Standardized Test Practice

10.9 si n 76° sin 48° ¬ c

14.2¬ c a2¬ b2 c2 2bccosA 192¬ 23.22 212 2(23.2)(21)cos A 361¬ 979.24 974.4cos A 618.24¬ 974.4cos A 618 .24 974.4 ¬ cosA

Pages 398–399 1. C; there is no information to support choices A, B, or D. 1 and 4 are vertical angles, and 2 and 3 are vertical angles. 2. D; AD¬ CD 3x 5¬ 5x 1 5¬ 2x 1 6¬ 2x 3¬ x AC AD CD AC 3x 5 5x 1 AC 3(3) 5 5(3) 1 AC 28

618 .24 A¬ cos1 974.4

A¬ 51° sin B A sin a ¬ b sin 5 1° sin B 19 ¬ 23.2

23.2sin51°¬ 19sinB 23.2 si n51° ¬ sinB 19 23.2 si n51° 1 ¬ B sin 19

SR PT 3. B; D C AE 6 S R 8 1 1

72°¬ B mA mB mC¬ 180 51 72 mC¬ 180 mC¬ 57 23.

11(SR) 48 48 4 SR 11 or 4 11 A C A B 4. C; AC ¬ AD 12 3 AC ¬ AC 12

B

A 9

(AC)2¬ 180 AC¬ 180 AC¬ 13.4 5. B; mRTS 180 135 or 45. RT (ST)2 52

0.5 mi

C

x

D

The ground and the horizontal level with the plane are parallel. Therefore, mBAD mADC

Chapter 7

B

Let x represent CB, the height of the incline. tan10°¬ 5x 5tan10°¬ x 0.9¬ x The height of the incline is about 0.9 mile. 25. D; Let y represent the unknown side length in the triangle. 52 y2¬ 132 25 y2¬ 169 y2¬ 144 y¬ 144 y¬ 12 1 2 tanX¬ 5

10.9 sin A¬ 12.2sin48°

22.

10

5 mi

C x

236

6. D; the height of the original tower is AB BC.

10. y y1¬ m(x x1)

60 sin36°¬ B C

y 32¬ 9 5 (x 0) y¬ 9 5 x 32

BCsin36°¬ 60 6 0 BC¬ sin 3 6° BC¬ 102 AB BC¬ 60 102 or 162 feet.

YZ X Z 11. U V TV 6 or 3 10 5 12. Let x represent Dee’s height above the water. x sin41°¬ 50 0 500sin41°¬ x 328¬ x Dee is about 328 feet above the water. 13. Since Sasha is equidistant from Toby and Rani, T S and S R are congruent and STR is an isosceles triangle. According to the Isosceles Triangle Theorem, T and R are also congruent. S X is perpendicular to T R , so SXT and SXR are both right angles and congruent. Two corresponding angles and the corresponding nonincluded sides are congruent (AAS Theorem), so STX and SRX are congruent triangles. Since these triangles are congruent, the corresponding sides T X and R X are congruent and have equal length; therefore when Sasha is jumping at Point X she will be at the midpoint between Toby and Rani.

R sin sin S r ¬ s sin 3 4° sin S 14 ¬ 21

7. C;

21sin34°¬ 14sinS 21sin 34° ¬ sinS 14 21s in 34° ¬ S sin1 14

57°¬ S 8. mC mBDC mDBC¬ 180 90 mBDC 55¬ 180 mBDC¬ 35 mADB mBDC¬ mADC mADB 35¬ 61 mADB¬ 26 mA mABD mADB 180 69 mABD 26 180 mABD 85 mABC mABD mDBC 85 55 140 y y

1 2 9. m x x 2

1

50 32 10 0 18 9 10 or 5

237

Chapter 7

Chapter 8 Quadrilaterals 0 a m b0

1. The angles measuring x° and 50° are supplementary. Find x. mx 50 180 mx 130 So, x is 130. 2. x° is the measure of the exterior angle of the triangle so its measure is the sum of the two remote interior angles or 25 20. So, x 45. 3. The measure of an internal angle of an equilateral triangle is 60. The angle measuring x° is supplementary to one of the angles. Find x. mx 60 180 mx 120 So, x is 120.

a b The slope is a b. y2 y1 10. The slope is given by m .

The slope is 1.

y y x2 x1

8-1

10 20 1 0 S T : 1 13 ¬ 14

Angles of Polygons

Page 406 Geometry Activity: Sum of the Exterior Angles of a Polygon

¬5 7

R S and T S are perpendicular since their slopes are opposite inverses.

1.

y y x2 x1

Polygon

number of exterior angles

sum of measure of exterior angles

triangle

3

360

quadrilateral

4

360

pentagon

5

360

hexagon

6

360

heptagon

7

360

2 1 5. The slope is given by m .

8 6 2 R S : 3 (9) 12 1 6

8 20 12 S T : 31 2 6 S R and T S are perpendicular since their slopes are opposite inverses.

2. The sum of the measures of the exterior angles is 360.

y y x2 x1


1) 3 ( 4 S R : 5 (6) 11 5 3 2 S T : 2 5 3

Page 407

RS and T S are not perpendicular since their slopes are not opposite inverses. y y x2 x1

82 6 T S : 3 5 8

3 4 S R and T S are perpendicular since their slopes are opposite inverses. y y x2 x1


m

d d2 c 2c d 2 32c


1. A concave polygon has at least one obtuse angle, which means the sum will be different from the formula. 2. Yes; an irregular polygon can be separated by the diagonals into triangles so the theorems apply. 3. Sample answer: regular quadrilateral:


84 4 S R : 3 (6) 3

x2 x1

ac m ¬ c (a) ac ¬ c a a c ¬ a c or 1


10 3 7 S R : 1 4 ¬ 5

y y x2 x1


Page 403 Getting Started

The sum of the interior angles is 360°. quadrilateral that is not regular:

3d c The slope is 3d c.

Chapter 8

The sum of the interior angles is 360°.

238

4. Use the Interior Angle Sum Theorem. S 180(n2) 180(5 2) 540 The sum of the measures of the interior angles of a pentagon is 540. 5. Use the Interior Angle Sum Theorem. S 180(n 2) 180(12 2) 1800 The sum of the measures of the interior angles of a dodecagon is 1800. 6. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (60)n ¬180(n 2) 60n ¬180n 360 0 ¬120n 360 360 ¬120n 3 ¬n The polygon has 3 sides. 7. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (90)n ¬180(n 2) 90n ¬180n 360 0 ¬90n 360 360 ¬90n 4 ¬n The polygon has 4 sides. 8. Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Write an equation to express the sum of the measures of the interior angles of the polygon. 360 mT mU mV mW 360 x (3x 4) x (3x 4) 360 8x 8 368 8x 46 x Use the value of x to find the measure of each angle. mT 46, mU 3 46 8 or 134, mV 46, and mW 3 46 8 or 134. 9. Since n 6, the sum of the measures of the interior angles is 180(6 2) or 720. Write an equation to express the sum of the measures of the interior angles of the polygon. 720 mJ mK mL mM mN mP 720 2x (9x 30) (9x 30) 2x (9x 30) (9x 30) 720 40x 120 600 40x 15 x Use the value of x to find the measure of each angle. mJ 30, mK 9 15 30 or 165, mL 9 15 30 or 165, mM 30, mN 9 15 30 or 165, and mP 9 15 30 or 165.

10. The sum of the measures of the exterior angles is 360. There are 6 congruent exterior angles. 6n 360 n 60 The measure of each exterior angle is 60. Since each exterior angle and its corresponding interior angle form a linear pair, the measure of the interior angle is 180 60 or 120. 11. The sum of the measures of the exterior angles is 360. There are 18 congruent exterior angles. 18n 360 n 20 The measure of each exterior angle is 20. Since each exterior angle and its corresponding interior angle form a linear pair, the measure of the interior angle is 180 20 or 160. 12. Use the Interior Angle Sum Theorem. S 180(n 2) 180(5 2) 540 The sum of the measures of the interior angles of the base of the fish tank is 540.

Pages 407–409 Practice and Apply 13. Use the Interior Angle Sum Theorem. S 180(n 2) 180(32 2) 5400 The sum of the measures of the interior a 32-gon is 5400. 14. Use the Interior Angle Sum Theorem. S 180(n 2) 180(18 2) 2880 The sum of the measures of the interior an 18-gon is 2880. 15. Use the Interior Angle Sum Theorem. S 180(n 2) 180(19 2) 3060 The sum of the measures of the interior a 19-gon is 3060. 16. Use the Interior Angle Sum Theorem. S 180(n 2) 180(27 2) 4500 The sum of the measures of the interior a 27-gon is 4500. 17. Use the Interior Angle Sum Theorem. S 180(n 2) 180(4y 2) 720y 360 360(2y 1) The sum of the measures of the interior a 4y-gon is 360(2y 1). 18. Use the Interior Angle Sum Theorem. S 180(n 2) 180(2x 2) 360(x 1) The sum of the measures of the interior a 2x-gon is 360(x 1).

239

angles of

angles of

angles of

angles of

angles of

angles of

Chapter 8

19. Use the Interior Angle Sum Theorem. S 180(n 2) 180(8 2) 1080 The sum of the measures of the interior angles of the octagonal garden is 1080. 20. Use the Interior Angle Sum Theorem. S 180(n 2) 180(6 2) 720 The sum of the measures of the interior angles of the hexagonal gazebos is 720. 21. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (140)n ¬180(n 2) 140n ¬180n 360 0 ¬40n 360 360 ¬40n 9 ¬n The polygon has 9 sides. 22. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (170)n ¬180(n 2) 170n ¬180n 360 0 ¬10n 360 360 ¬10n 36 ¬n The polygon has 36 sides. 23. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (160)n ¬180(n 2) 160n ¬180n 360 0 ¬20n 360 360 ¬20n 18 ¬n The polygon has 18 sides. 24. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (165)n ¬180(n 2) 165n ¬180n 360 0 ¬15n 360 360 ¬15n 24 ¬n The polygon has 24 sides. 25. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (157.5)n ¬180(n 2) 157.5n ¬180n 360 0 ¬22.5n 360 360 ¬22.5n 16 ¬n The polygon has 16 sides.

Chapter 8

26. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (176.4)n ¬180(n 2) 176.4n ¬180n 360 0 ¬3.6n 360 360 ¬3.6n 100 ¬n The polygon has 100 sides. 27. Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Write an equation to express the sum of the measures of the interior angles of the polygon. 360 mM mP mQ mR 360 x 4x 2x 5x 360 12x 30 x Use the value of x to find the measure of each angle. mM 30, mP 4 30 or 120, mQ 2 30 or 60, and mR 5 30 or 150. 28. Since n 5, the sum of the measures of the interior angles is 180(5 2) or 540. Write an equation to express the sum of the measures of the interior angles of the polygon. 540 mE mF mG mH mJ 540 x (x 20) (x 5) (x 5) (x 10) 540 5x 30 510 5x 102 x Use the value of x to find the measure of each angle. mE 102, mF 102 20 or 122, mG 102 5 or 107, mH 102 5 or 97, and mJ 102 10 or 112. 29. Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Since a parallelogram has congruent opposite angles, the measures of angles M and P are equal, and the measures of angles N and Q are equal. Write an equation to express the sum of the measures of the interior angles of the parallelogram. 360 mM mN mP mQ 360 10x 20x 10x 20x 360 60x 6x Use the value of x to find the measure of each angle. mM 10 6 or 60, mN 20 6 or 120, mP 10 6 or 60, and mQ 20 6 or 120. 30. Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Write an equation to express the sum of the measures of the interior angles of the isosceles trapezoid. 360 mT mW mY mZ 360 20x 20x 30x 30x 360 100x 3.6 x Use the value of x to find the measure of each angle. mT 20 3.6 or 72, mW 20 3.6 or 72, mY 30 3.6 or 108, and mZ 30 3.6 or 108.

240

31. Since n 10, the sum of the measures of the interior angles is 180(10 2) or 1440. The sum of the given measures is 10x 440. Find x. 1440 10x 440 1000 10x 100 x The measures of the interior angles of the decagon are 105, 110, 120, 130, 135, 140, 160, 170, 180, and 190. 32. Since n 5, the sum of the measures of the interior angles is 180(5 2) or 540. Write an equation to express the sum of the measures of the interior angles of the polygon. 540 mA mB mC mD mE 540 6x (4x 13) (x 9) (2x 8) (4x 1) 540 17x 13 527 17x 31 x Use the value of x to find the measure of each angle. mA 6 31 or 186, mB 4 31 13 or 137, mC 31 9 or 40, mD 2 31 8 or 54, and mE 4 31 1 or 123. 33. Sample answer: Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Write an equation to express the sum of the measures of the interior angles of the quadrilateral. 360 x 2x 3x 4x 360 10x 36 x The measures of the interior angles of the quadrilateral are 36, 2 36 or 72, 3 36 or 108, and 4 36 or 144. 34. Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Write an equation to express the sum of the measures of the interior angles of the quadrilateral. 360 x (x 10) (x 20) (x 30) 360 4x 60 300 4x 75 x The measures of the interior angles of the quadrilateral are 75, 75 10 or 85, 75 20 or 95, and 75 30 or 105. 35. The sum of the measures of the exterior angles is 360. A regular decagon has 10 congruent exterior angles. 10n 360 n 36 The measure of each exterior angle is 36. Since each exterior angle and its corresponding interior angle form a linear pair, the measure of the interior angle is 180 36 or 144. 36. The sum of the measures of the exterior angles is 360. A regular hexagon has 6 congruent exterior angles. 6n 360 n 60 The measure of each exterior angle is 60. Since each exterior angle and its corresponding interior angle form a linear pair, the measure of the interior angle is 180 60 or 120.

37. The sum of the measures of the exterior angles is 360. A regular nonagon has 9 congruent exterior angles. 9n 360 n 40 The measure of each exterior angle is 40. Since each exterior angle and its corresponding interior angle form a linear pair, the measure of the interior angle is 180 40 or 140. 38. The sum of the measures of the exterior angles is 360. A regular octagon has 8 congruent exterior angles. 8n 360 n 45 The measure of each exterior angle is 45. Since each exterior angle and its corresponding interior angle form a linear pair, the measure of the interior angle is 180 45 or 135. 39. Since n 11, the sum of the measures of the interior angles is 180(11 2) or 1620. A regular 11-gon has 11 congruent interior angles. Let the measure of one of these angles be x. 1620 11x 147.3 x To the nearest tenth, the measure of each interior angle of the 11-gon is 147.3. Since each interior angle and its corresponding exterior angle form a linear pair, the measure of the exterior angle is about 180 147.3 or 32.7. 40. Since n 7, the sum of the measures of the interior angles is 180(7 2) or 900. A regular 7-gon has 7 congruent interior angles. Let the measure of one of these angles be x. 900 7x 128.6 x To the nearest tenth, the measure of each interior angle of the 7-gon is 128.6. Since each interior angle and its corresponding exterior angle form a linear pair, the measure of the exterior angle is about 180 128.6 or 51.4. 41. Since n 12, the sum of the measures of the interior angles is 180(12 2) or 1800. A regular 12-gon has 12 congruent interior angles. Let the measure of one of these angles be x. 1800 12x 150 x The measure of each interior angle of the 12-gon is 150. Since each interior angle and its corresponding exterior angle form a linear pair, the measure of the exterior angle is about 180 150 or 30. 42. Consider the sum of the measures of the exterior angles, N, for an n-gon. N sum of measures of linear pairs sum of measures of interior angles 180n 180(n 2) 180n 180n 360 360 So, the sum of the exterior angle measures is 360 for any convex polygon.

241

Chapter 8

9y 2x

43. Since n 5, the sum of the measures of the interior angles is 180(5 2) or 540. A regular pentagon has 5 congruent interior angles. Let the measure of one of these angles be x. 540 5x 108 x The measure of each interior angle of the Pentagon is 108. Since each interior angle and its corresponding exterior angle form a linear pair, the measure of the exterior angle is 180 108 or 72. 44. Yes; both the dome and the architectural elements are based upon a regular octagon. Since n 8, the sum of the measures of the interior angles is 180(8 2) or 1080. A regular octagon has 8 congruent interior angles. Let the measure of one of these angles be x. 1080 8x 135 x The measure of each interior angle is 135. Since each interior angle and its corresponding exterior angle form a linear pair, the measure of the exterior angle is about 180 135 or 45.

48. Since 9, y 2x. Substitute this result into the other equation relating x and y. Then solve for x. 6x 3y ¬48 6x 3(2x) ¬48 6x 6x ¬48 12x ¬48 x ¬4

Page 409 Maintain Your Skills 49. Use the Law of Cosines to find mC since the measures of all three sides are known. c2 ¬a2 b2 2ab cosC 112 ¬62 92 2(6)(9)cos C 121 ¬36 81 108 cosC 4 ¬108 cosC 4 108 ¬cosC 1 C ¬cos1 27

C ¬92.1 To the nearest tenth, the measure of angle C is 92.1.

180(n 2) 180n 360 45. n n n 180 360 n n 360 180 n

50. Use the Law of Cosines to find mB since the measures of all three sides are known. b2 ¬a2 c2 2ac cos B 23.62 ¬15.52 25.12 2(15.5)(25.1)cos B 556.96 ¬240.25 630.01 778.1 cos B 313.3 ¬778.1 cos B

The two formulas are equivalent.

46. Sample answer: The outline of a scallop shell is a convex polygon that is not regular. The lines in the shell resemble diagonals drawn from one vertex of a polygon. These diagonals separate the polygon into triangles. Answers should include the following. • The Interior Angle Sum Theorem is derived from the pattern between the number of sides in a polygon and the number of triangles. The formula is the product of the sum of the measures of the angles in a triangle, 180, and the number of triangles the polygon contains. • The exterior angle and the interior angle of a polygon are a linear pair. So, the measure of an exterior angle is the difference between 180 and the measure of the interior angle. 47. B; since the unknown polygon is regular, its interior angles are congruent. The sum of the measures of the interior angles of the square, pentagon, and unknown regular polygon is 360. Let the measure of each interior angle of the unknown polygon be x. Find x using the fact that the measures of the interior angles of squares and regular pentagons are 90 and 108, respectively. 360 x 90 108 162 x The sum of the measures of the interior angles is given by S 180(n 2), the Interior Angle Sum Theorem. This is equal to 162n, where, in both cases, n is the number of sides. Solve for n. 162n ¬180(n 2) 162n ¬180n 360 0 ¬18n 360 360 ¬18n 20 ¬n The polygon has 20 sides.

Chapter 8

31 3.3 778.1 ¬cos B

313 .3 B ¬cos1 778.1

B ¬66.3 To the nearest tenth, the measure of angle B is 66.3. 51. Use the Law of Cosines to find mA since the measures of all three sides are known. a2 ¬b2 c2 2ab cos A 472 ¬532 562 2(53)(56) cos A 2209 ¬2809 3136 5936 cos A 3736 ¬5936 cos A 37 36 5936 ¬cos A

46 7 A ¬cos1 742

A ¬51.0 To the nearest tenth, the measure of angle A is 51.0. 52. Use the Law of Cosines to find mC since the measures of all three sides are known. c2 ¬a2 b2 2ab cos C 162 ¬122 142 2(12)(14)cos C 256 ¬144 196 336 cos C 84 ¬336 cos C 84 3 36 ¬cos C

C ¬cos1 1 4

C ¬75.5 To the nearest tenth, the measure of angle C is 75.5.

242

53. Use the Law of Sines since we know the measures of two sides and an angle opposite one of the sides. G F sin sin g ¬ f sin G sin 5 4° 17 ¬ 15 17sin 54° sin G ¬ 15 17sin 54° G ¬sin1 15

56. Use the Law of Sines since we know the measures of two sides and an angle opposite one of the sides. H G sin sin h ¬ g sin H sin 6 5° 32.4 ¬ 30.7 32.4 si n 65° sin H ¬ 30.7 32.4 si n 65° H ¬sin1 30.7

H ¬73° Use the Angle Sum Theorem to find mF. mF mG mH ¬180 mF 65 73 ¬180 mF ¬42 Use the Law of Sines to find f.

G ¬66° Use the Angle Sum Theorem to find mH. mF mG mH ¬180 54 66 mH ¬180 mH ¬60 Use the Law of Sines to find h. F H sin sin f ¬ h

sin F G sin g ¬ f sin 6 5° sin 42° 30.7 ¬ f 30 .7 si n 42° f ¬ sin 65°

sin 5 4° sin 60° 15 ¬ h 15 s in 60° h ¬ sin 54°

h ¬16.1 Therefore, mG 66, mH 60, and h 16.1.

f ¬22.7 Therefore, mH 73, mF 42, and f 22.7.

54. Use the Angle Sum Theorem to find mG. mF mG mH ¬180 47 mG 78 ¬180 mG ¬55 Use the Law of Sines to find f and h.

57. Given: J L K M , J K L M Prove: JKL MLK J K

G sin sin F g ¬f sin 5 5° sin 47° 31 ¬ f 31 s in 47° f ¬ sin 55°

L

M

Proof: Statements

f ¬27.7

1. JL K M , J K L M 2. MKL JLK, JKL MLK 3. K L K L 4. JKL MLK

G sin sin H g ¬h sin 5 5° sin 78° 31 ¬ h 31 s in 78° h ¬ sin 55°

h ¬37.0 Therefore, mG 55, f 27.7, and h 37.0.

Reasons 1. Given 2. Alt. int. are . 3. Reflexive Property 4. ASA

58. Line b is the transversal that forms 3 and 11 where it intersects lines m and n. 3 and 11 are corresponding angles. 59. Line m is the transversal that forms 6 and 7 where it intersects lines b and c. 6 and 7 are consecutive interior angles. 60. Line c is the transversal that forms 8 and 10 where it intersects lines m and n. 8 and 10 are alternate interior angles. 61. Line n is the transversal that forms 12 and 16 where it intersects lines b and c. 12 and 16 are alternate exterior angles. 62. 1 and 4, 1 and 2, 2 and 3, and 3 and 4 are consecutive interior angles. 63. 3 and 5, and 2 and 6 are alternate interior angles. 64. 1 and 5, and 4 and 6 are corresponding angles. 65. None; there are no pairs of alternate exterior angles.

55. Use the Angle Sum Theorem to find mF. mF mG mH ¬180 mF 56 67 ¬180 mF ¬57 Use the Law of Sines to find f and h. G sin sin F g ¬f sin 5 6° sin 57° 63 ¬ f 63 sin 57° f ¬ sin 56 °

f ¬63.7 G sin sin H g ¬h sin67° sin 5 6° 63 ¬ h 63 sin 67° h ¬ sin 56°

h ¬70.0 Therefore, mF 57, f 63.7, and h 70.0.

243

Chapter 8

6. Since consecutive angles in parallelograms are supplementary, TSR is supplementary to STQ and SRQ. 7. MJK KLM because opposite angles in a parallelogram are congruent. Find mKLM. mKLM mKLR mMLR 70 30 100 So, mMJK 100. 8. Consecutive angles in a parallelogram are supplementary. So, mJML 180 mKLM. mJML 180 100 or 80. 9. Consecutive angles in a parallelogram are supplementary. So, mJKL 180 mKLM. mJKL 180 100 or 80. 10. KJL JLM because they are alternate interior angles. The measure of JLM is 30. So, mKJL 30. 11. Opposite sides of a parallelogram are congruent, so their measures are equal. Find a. JM ¬KL 3a ¬21 a ¬7 12. Opposite sides of a parallelogram are congruent, so their measures are equal. Find b. JK ¬ML 2b 3 ¬45 2b ¬42 b ¬21 13. Given: VZRQ and WQST Prove: Z T Q R S

Page 410 Spreadsheet Investigation: Angles of Polygons 1. For a regular polygon, the measure of each interior angle in the polygon can be found by dividing the sum of the measures of the interior angles by the number of sides of the polygon. So, the formula to find the measure of each interior angle in the polygon is “C2/A2”. 2. For a regular polygon, the sum of the measures of the exterior angles of the polygon can be found by multiplying the number of sides by the measure of the exterior angles. So, the formula to find the sum of the measures of the exterior angles of the polygon is “A2*E2”. 3. The formula for the sum of the measures of the interior angles is “(A2-2)*180”, which gives 180 for 1 side and 0 for 2 sides. 4. No, a polygon is a closed figure formed by coplanar segments. 5. A 15-sided polygon has 13 triangles. 6. The measure of the exterior angle of a 15-sided polygon is 24. 7. The measure of the interior angle of a 110-sided polygon is about 176.7. 8. Each interior angle measures 180. This is not possible for a polygon.

8-2

Parallelograms

Pages 411–412 Geometry Activity: Properties of Parallelograms

W

1. FG H J P Q R S and F J G H P S Q R . 2. F P H R and J G Q S. 3. Opposite angles are congruent; consecutive angles are supplementary.

Page 414

T V

Z Proof: Statements 1. VZRQ and WQST 2. Z Q, Q T 3. Z T


1. Opposite sides are congruent; opposite angles are congruent; consecutive angles are supplementary; and if there is one right angle, there are four right angles. 2. Diagonals bisect each other; each diagonal forms two congruent triangles in a parallelogram. 3. Sample answer:

1. Given 2. Opp. of a are . 3. Transitive Prop.

Z W S 14. Given: XYRZ, W Prove: XYR S W Y

X

x 2x

Z

4. SV V Q because diagonals of parallelograms bisect each other. 5. Since diagonals bisect each other and opposite sides of parallelograms are congruent, VRS VTQ by SSS.

Chapter 8

Reasons

R

S

Proof: Opposite angles of a parallelogram are congruent, so Z XYR. By the Isosceles Triangle Theorem, since W Z W S , Z S. By the Transitive Property, XYR S.

244

15. C; G J and H K are the diagonals. Since the diagonals of a parallelogram bisect each other, the intersection point is the midpoint of G J and H K. Find the intersection of the diagonals by finding the midpoint of G J .

30. The diagonals of a parallelogram bisect each other, so MQ QP. Find w. MQ ¬QP 4w 3 ¬11.1 4w ¬14.1 w ¬3.5 31. The diagonals of a parallelogram bisect each other, so RQ QN. Find z. RQ ¬QN 3z 3 ¬15.4 3z ¬18.4 z ¬6.1

x1 x2 y1 y2

3 3 4 (5) 2, 2 2 2 ,

(0, 0.5) The diagonals intersect at (0, 0.5).

Pages 415–416

Practice and Apply

16. DAB BCD because opposite angles of a parallelogram are congruent. 17. ABD CDB because alternate interior angles are congruent. 18. A B D C because opposite sides of a parallelogram are parallel. 19. B G G D because the diagonals of a parallelogram bisect each other. 20. ABD CDB because the diagonal B D separates the parallelogram into two congruent triangles. 21. ACD BAC because alternate interior angles are congruent. 22. RNP NRM because they are alternate interior angles. So, mRNP 38. Find mMNP. mMNP mMNR mRNP 33 38 71 23. NRP MNR because they are alternate interior angles. So, mNRP 33. 24. RNP MRN because they are alternate interior angles. So, mRNP 38. 25. RMN is supplementary to MNP. Find mRMN. mRMN mMNP ¬180 mRMN 71 ¬180 mRMN ¬109 26. MQN is supplementary to PQN. Find mMQN. 180 mMQN mPQN 180 mMQN 83 97 mMQN 27. MQR PQN because they are vertical angles. So, mMQR 83. 28. Opposite sides of a parallelogram are congruent, so their measures are equal. Find x. MN ¬RP 3x 4 ¬20 3x ¬24 x ¬8 29. Opposite sides of a parallelogram are congruent, so their measures are equal. Find y. NP ¬MR 2y 5 ¬17.9 2y ¬12.9 y ¬6.45

32. The diagonals of a parallelogram bisect each other, so EJ JG. Find x. EJ ¬JG 2x 1 ¬3x 1 ¬x EG EJ JG [2(1) 1] 3(1) 6 33. The diagonals of a parallelogram bisect each other, so HJ JF. Find y. HJ ¬JF 1y 2 ¬y 1 2 2 1 2 1 2 ¬y 2 y 5 ¬1 y 2 2

5 ¬y FH HJ JF

1 ¬ 1 2 (5) 2 5 2

¬9 34. Since the diagonals of a parallelogram bisect each other, the drawer pulls are at the intersection point of the diagonals. 35. B A 3a

3

b

1

a

18

2b

P 12a

C D Since ABCD is a parallelogram, the diagonals bisect each other. So AC 2(AP) AC 12a and AP 3a 18 12a ¬2(3a 18) 12a ¬6a 36 6a ¬36 a ¬6 DP PB 3b 1 a 2b 3b 1 6 2b b5 DB 2(3b 1) 2(3 5 1) 2(16) 32 So, a 6, b 5, and DB 32.

245

Chapter 8

36. A

40. They are all congruent parallelograms. Since A, B and C are midpoints, A C , A B , and B C are midsegments. The midsegment is parallel to the third side and equal to half the length of the third side. So, each pair of opposite sides of ACBX, ABYC, and ABCZ are parallel. 41. Given: PQRS Prove: P Q R S R Q S P

B 2x 5 2y 120 21

D

21

C

P 1

Opposite sides of a parallelogram are congruent, so A B C D and AB CD. Find x. AB ¬CD 2x 5 21 2x ¬16 x ¬8 Consecutive angles in a parallelogram are supplementary, so B is supplementary to BAD and mBAD mCAD mBAC. Find y. mBAD mB ¬180 mCAD mBAC mB ¬180 21 2y 120 ¬180 2y ¬39 y ¬19.5 37. The Distance Formula is d (x x1)2 (y2 y1)2. 2 The diagonals bisect each other if EQ QG and HQ QF. Find these measures. 2 (1 EQ (3 0) 5)2 5 2 ( QG (6 3) 3 1)2 5 2 [1 HQ (3 0) (1)] 2 13 2 (3 QF (6 3) 1)2 13 The diagonals do indeed bisect each other. 38. If EG FH, the diagonals are congruent. Use the Distance Formula to find EG and FH. d (x2 x1)2 (y2 y1)2 2 EG (6 0) ( 3 5)2 10 2 ( FH (0 6) 1 3)2 52 2 13 No, the diagonals are not congruent, since EG FH. 39. E H is vertical, so its slope is undefined. Find the slope of E F .

4

2

S R Proof: Statements

Reasons

1. Given 1. PQRS 2. Diagonal of PQRS 2. Draw an auxiliary segment P R and label angles 1, 2, 3, and 4 as shown. 3. Opp. sides of are . 3. P Q S R , P S Q R 4. Alt. int. are . 4. 1 2, and 3 4 5. Reflexive Prop. 5. P R P R 6. ASA 6. QPR SRP 7. CPCTC 7. P Q R S and R Q S P 42. Given: GKLM Prove: G and K are supplementary. K and L are supplementary. L and M are supplementary. M and G are supplementary. G

K

M L Proof: Statements 1. GKLM 2. G K M L , G MK L 3. G and K are supplementary. K and L are supplementary. L and M are supplementary. M and G are supplementary.

y y x2 x1 3 5 ¬ 60 ¬1 3

2 1 m ¬

No, the consecutive sides are not perpendicular because the slopes of the sides are not opposite reciprocals of each other.

Chapter 8

Q

3

246

Reasons 1. Given 2. Opp. sides of are . 3. Cons. int. are suppl.

43. Given: MNPQ M is a right angle. Prove: N, P and Q are right angles M N

4. HFG and DJK are rt. . 5. HFG and DJK are rt. s. 6. HFG DJK

Q P Proof: By definition of a parallelogram, M N Q P . Since M is a right angle, M Q M N . By the Perpendicular Transversal Theorem, M Q Q P . Q is a right angle, because perpendicular lines form a right angle. N Q and M P because opposite angles in a parallelogram are congruent. P and N are right angles, since all right angles are congruent. 44. Given: ACDE is a parallelogram. Prove: E C bisects A D . A D bisects E C . A

B

1. BCGH HD F D 2. F H

C

1. WXYZ 2. W X Z Y , W Z X Y 3. ZWX XYZ 4. WXZ YZX

so TP 1 2 MN.

M. S Find SP M S M R SP TP 1 MN 4 1 MN 2 1 2 The ratio of MS to SP is 1 2. 49. Sample answer: The graphic uses the illustration of wedges shaped like parallelograms to display the data. Answers should include the following. • The opposite sides are parallel and congruent, the opposite angles are congruent, and the consecutive angles are supplementary. • Sample answer:

Reasons 1. 2. 3. 4.

Given Opp. sides of are . Opp. of are . SAS

Percent That Use the Web

100

D

H J K Proof: Statements

2. Isosceles Triangle Theorem 3. Opp. of are . 4. Congruence of angles is transitive.

48. MSR PST because they are vertical angles. NMP MPQ because they are alternate interior angles. So, MSR is similar to PST. N M Q P because opposite sides of a parallelogram are congruent. TP 1 2 QP is given,

46. Given: DGHK is a parallelogram. H F G D J D H K Prove: DJK HFG G F

1. Given

3. H GCB 4. F GCB

X

Z Y Proof: Statements

6. HA

D F D 47. Given: BCGH, H Prove: F GCB H B G D F C Proof: Statements Reasons

E D Proof: It is given that ACDE is a parallelogram. Since opposite sides of a parallelogram are congruent, E AD C . By definition of a parallelogram, E A D C . AEB DCB and EAB CDB because alternate interior angles are congruent. EBA CBD by ASA. E B B C and A B B D by CPCTC. By the definition of segment bisector, E C bisects A D and A D bisects C E . 45. Given: WXYZ Prove: WXZ YZX W

4. lines form four rt. . 5. Def. of rt.

1. DGHK is a 1. Given parallelogram. H F G D , D J H K 2. G K 2. Opp. of are . 3. Opp. sides of are . 3. G H D K

60%

60 40 29% 20 0

Reasons

79%

80

1998 1999 2000 Year

50. Consecutive angles of a parallelogram are supplementary. Find x (3x 42) (9x 18) ¬180 12x 24 ¬180 12x ¬156 x ¬13 3(13) 42 81 9(13) 18 99 The measures of the angles are 81 and 99.

247

Chapter 8

51. B; the perimeter p is equal to the sum of the measures of the sides. Find y. 2x 2y ¬p

57. Since the measures of two sides and an angle opposite one of the sides are known, use the Law of Sines.

y 5 2y 2y ¬p 5 12y ¬p 5 5p y ¬ 12

C B sin sin c ¬ b sin C sin 5 7° 14 ¬ 12.5 14 sin 57° sinC ¬ 12.5 14 sin 57° C ¬sin1 12.5

2 2y ¬p

Page 416

mC ¬69.9

Use the Angle Sum Theorem. mA mB mC ¬180 mA 57 69.9 ¬180 mA ¬53.1


52. Use the Interior Angle Sum Theorem. S 180(n 2) 180(14 2) 2160 The sum of the measures of the interior angles of a 14-gon is 2160. 53. Use the Interior Angle Sum Theorem. S 180(n 2) 180(22 2) 3600 The sum of the measures of the interior angles of a 22-gon is 3600. 54. Use the Interior Angle Sum Theorem. S 180(n 2) 180(17 2) 2700 The sum of the measures of the interior angles of a 17-gon is 2700. 55. Use the Interior Angle Sum Theorem. S 180(n 2) 180(36 2) 6120 The sum of the measures of the interior angles of a 36-gon is 6120. 56. Since the measures of two sides and the included angle are known, use the Law of Cosines. a2 b2 c2 2bc cos A a2 112 132 2(11)(13) cos 42° a 112 132 2(11)(13) cos 42° a 8.8 b2 ¬a2 c2 2ac cos B 112 ¬8.82 132 2(8.8)(13) cos B 125.44 ¬2(8.8)(13) cos B

B A sin sin b ¬ a sin 5 7° sin5 3.1° a 12.5 ¬ 12.5 sin 53.1° a ¬ sin 57°

a ¬11.9 58. Since the measures of two sides and the included angle are known, use the Law of Cosines. c2 a2 b2 2ab cos C c2 212 242 2(21)(24) cos 78° c ¬ 212 242 2(21) (24) cos 78° c ¬28.4 a2 ¬b2 c2 2bc cos A 212 ¬242 28.42 2(24)(28.4) cos A 941.56 ¬1363.2 cos A 941 .56 1363.2 ¬cos A 941 .56 cos1 1363.2 ¬A

Use the Angle Sum Theorem. mA mB mC ¬180 46.3 mB 78 ¬180 mB ¬55.7 59. The numbers of the outside diagonals are all ones, so the first thirty numbers sum to 30. 60. The second diagonal consists of the natural numbers, 1, 2, 3, 4, 5, . . . , 70. The sum is 1 2 3 4 . . . 67 68 69 70 ¬(1 70) (2 69) (3 68) . . . (35 + 36) ¬35(71) ¬2485 The sum of the first 70 numbers is 2485.

125 .44 228.8 ¬cos B 125 .44 cos1 228.8 ¬B

56.8 ¬mB Use the Angle Sum Theorem. mA mB mC ¬180 42 56.8 mC ¬180 mC ¬81.2

Chapter 8

46.3 ¬mA

248

61. 8

5. Opposite sides are parallel and congruent, opposite angles are congruent, or consecutive angles are supplementary.

y

B 4 8

4

O

A

4

C

4

8x

Pages 420–421

D AB is a side. Find the slope of A B . y y x2 x1 5 (2) 2 (5) 7 3

2 1 m

62. 8

A D 3. Shaniqua; Carter’s description could result in a shape that is not a parallelogram. 4. No; one pair of opposite sides is not parallel and congruent. 5. Yes; the missing angle measure of the parallelogram is 180 102 or 78, so each pair of opposite angles is congruent. 6. Opposite sides of a parallelogram are congruent. Find x and y. 2x 5 3x 18 13 x 2y 12 ¬5y 12 ¬3y 4 ¬y 7. Opposite angles of a parallelogram are congruent. Find x and y. 3x 17 2x 24 x 41 5y 6 ¬y 58 4y ¬64 y ¬16 8. Yes;

y

B 4 8

4

O

A

4

C

4

8x

D D B is a diagonal. Find the slope of B D . y y x2 x1 9 5 1 (2)

2 1 m

14 63. 8

y

B 4 8

4

A

O 4

4

C


1. Both pairs of opposite sides are congruent; both pairs of opposite angles are congruent; diagonals bisect each other; one pair of opposite sides is parallel and congruent. 2. Sample answer: B C

8x

y

E

D

D

D C is a side. Find the slope of C D . y y x2 x1 9 (2) 1 2 7 3

2 1 m

8-3

C B O

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram. y y x2 x1 1 0 40 1 4 4 5 slope of D E 26 1 4 4 0 slope of B E 20

2 1 slope of B C

Tests for Parallelograms

Page 417 Geometry Activity: Testing for a Parallelogram 1. 2. 3. 4.

x

They appear to be parallel. The quadrilaterals formed are parallelograms. The measures of pairs of opposite sides are equal. Opposite angles are congruent, and consecutive angles are supplementary.

2 5 1 slope of C D 64 2

249

Chapter 8

Since opposite sides have the same slope, B C D E and B E C D . Therefore, BCDE is a parallelogram by definition. 9. Yes;

11. Given: P T T R TSP TQR Prove: PQRS is a parallelogram. P

Q T

y

S Proof:

C D

Statements B x

O

A

First use the Distance Formula to determine whether the opposite sides are congruent. AD (x2 x1)2 (y2 y1)2 2 (3 [6 (4)] 0)2 13 BC (1 3 )2 (4 1)2 13 Since AD BC, A D B C . Next, use the Slope Formula to determine whether A D B C .

13. 14. 15. 16. 17.

y

18.

G H

19. x O

F E If the midpoints of the diagonals are the same, the diagonals bisect each other. If the diagonals of a quadrilateral bisect each other, then the quadrilateral is a parallelogram. Find the midpoints of E G and F H . y y

20.

3 (3)

4 2 1 2 1 2 G E : 2, 2 ¬2, 2

¬(1, 0)

x1 x2 y1 y2 4 (6) 1 2 H F : 2, 2 ¬ 2, 2

¬1, 1 2

The midpoints of E G and F H differ, so EFGH is not a parallelogram.

Chapter 8

3. PTS RTQ 4. P S Q R 5. P S Q R

3. AAS 4. CPCTC 5. If alternate interior angles are congruent, lines are parallel. 6. If one pair of opposite sides is parallel and congruent, then the quadrilateral is a parallelogram.

2. Vertical angles are congruent.


AD and B C have the same slope, so they are parallel. Since one pair of opposite sides is congruent and parallel, ABCD is a parallelogram. 10. No;

x x

1. Given

12. If one pair of opposite sides is congruent and parallel, the quadrilateral is a parallelogram.

2 1 D slope of A

Reasons

1. PT T R , TSP TQR 2. PTS RTQ

6. PQRS is a parallelogram.

y y x2 x1 30 6 (4) 3 2 4 slope of B C 11 3 3 2

R

250

Yes; each pair of opposite angles is congruent. Yes; the diagonals bisect each other. Yes; opposite angles are congruent. No; none of the tests for parallelograms are fulfilled. Yes; one pair of opposite sides is parallel and congruent. No; none of the tests for parallelograms are fulfilled. Opposite sides of a parallelogram are congruent. Find x and y. 2x ¬5x 18 18 ¬3x 6 ¬x 3y ¬96 y 4y ¬96 y ¬24 Diagonals of a parallelogram bisect each other. Find x and y. 2x 3 ¬5x 3 ¬3x 1 ¬x 4y ¬8y 36 36 ¬4y 9 ¬y

21. Opposite sides of a parallelogram are congruent. Find x and y. y 2x ¬4 y ¬2x 4 5y 2x ¬3y 2x 2y ¬4x y ¬2x Find x. 2x ¬2x 4 4x ¬4 x ¬1 So, y 2(1) or 2. 22. Since the opposite sides of a parallelogram are parallel, there are two pairs of alternate interior angles formed by the diagonal of the parallelogram. Find x and y. 25x ¬100 x ¬4 10y ¬40 y ¬4 23. Since the opposite sides of a parallelogram are parallel, there are two pairs of alternate interior angles formed by the diagonal of the parallelogram. Find y in terms of x.

25. Yes; y

G

E

x

O

B

C

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram. y y

2 1 slope of B C x x 2

1

3 (3)

¬ 2 (6)

¬0

4 4 G slope of E 4 4

¬0

4 (3)

G slope of B 4 (6) ¬7 2

4 (3)

slope of C E 42 ¬7 2

Since opposite sides have the same slope, B C E G and B G C E . Therefore, BCEG is a parallelogram by definition. 26. No;

1 y ¬x 12 2

y ¬2x 24 Opposite angles of a parallelogram are congruent. Find another equation for y in terms of x. 3y 4 ¬4x 8 3y ¬4x 4 4 y ¬4 3x 3 Find x by setting the two expressions for y equal to each other

y

8

S 4

T 8

4

R x

O 4

4

4x 4 ¬2x 24 3 3 68 ¬2x 3 3

Q

8

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram.

34 ¬x So, y 2(34) 24 or 44. 24. Diagonals of a parallelogram bisect each other. Find y in terms of x. 3y 4 ¬x 3y ¬x 4 4 y ¬1 3x 3

y y

2 1 slope of Q R x x 2

1

2 (6)

¬ 2 (3) ¬8 5

26 slope of S T 5 (1) ¬1 The opposite sides, Q R and S T , do not have the same slope, so they are not parallel. Therefore, QRST is not a parallelogram. 27. Yes;

4y ¬2 3x

y ¬1 6x Find x by setting the two expressions for y equal to each other. 1x ¬1x 4 6 3 3 4 ¬1x 3 6

y

C

D

8 ¬x 1 So, y 1 6 (8) or 1 3 .

x

O

B A

If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a

251

Chapter 8

parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent. AD ¬ (x2 x1)2 (y2 y1)2 2 ¬ [4 (5)] [2 (4)] 2 ¬ 37 BC ¬ (4 3 )2 [4 (2 )]2 ¬ 37 AB ¬ [3 ( 5)]2 [2 (4)] 2 ¬ 68 CD ¬ (4 4)2 (2 4 )2 ¬ 68 Since the measures of both pairs of opposite sides are equal, ABCD is a parallelogram. 28. Yes;

30. No; 8

J O

L K

8

If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent. HJ ¬ (x2 x1)2 (y2 y1)2 2 2 ¬ (9 5 ) (0 6) ¬ 52 KL ¬ (3 8 )2 [ 2 ( 5)]2 ¬ 34 Since HJ KL, H J K L . Therefore, HJKL is not a parallelogram. 31. Yes;

x

X W

y

S

If the midpoints of the diagonals are the same, the diagonals bisect each other. If the diagonals of a quadrilateral bisect each other, then the quadrilateral is a parallelogram. Find the midpoints of W Y and X Z .

x1 x2 y1 y2 1 6 9 2 V S : 2, 2 ¬ 2, 2

1 1 ¬5 2, 2 x x y y 3 8 2 3 W T : 2, 2 ¬ 2 , 2 11 ¬5 2, 2

29. No;

1

G 8 y

O

4

4

x

O

¬(3, 3) The midpoints of W Y and X Z are the same, so WXYZ is a parallelogram.

4

V

If the midpoints of the diagonals are the same, the diagonals bisect each other. If the diagonals of a quadrilateral bisect each other, then the quadrilateral is a parallelogram. Find the midpoints of S V and W T .

¬(3, 3)

T

W

x1 x2 y1 y2 1 (5) 4 (2) Z X : 2, 2 ¬ 2, 2

H 8

4

2

1

2

The midpoints of S V and W T are the same, so STVW is a parallelogram. 32. Yes;

12 x

J

y

K

8

C D

First use the Distance Formula to determine whether the opposite sides are congruent. GH ¬ (x2 x1)2 (y2 y1)2

O x

¬ [4 ( 2)]2 (4 8)2

G

¬ 52 JK ¬ (1 6)2 [7 (3)]2 ¬ 65 Since GH JK, G H J K . Therefore, GHJK is not a parallelogram.

Chapter 8

x

8

4

4

Z

x1 x2 y1 y2 5 (1) 6 0 ¬ Y W : 2 , 2 2 2 ,

H

4

y OY

y

F

First use the Distance Formula to determine whether the opposite sides are congruent. CD ¬ (x2 x1)2 (y2 y1)2 2 ¬ [3 (7)] (2 3)2 ¬ 17

252

R slope of N P slope of M

FG ¬ (4 0)2 [3 (4)]2 ¬ 17 Since CD FG, C D F G . Next, use the Slope Formula to determine whether C D F G .

y (1) 8 1 ¬ x (1) y1 8 x 1 1 ¬

Again, x 0 and y 9. So, move P to (0, 9).

y2 y1 D slope of C x2 x1 2 3 ¬ 3 (7) ¬1 4 3 (4) slope of F G ¬ 4 0 1 ¬ 4

N slope of P R Move R: slope of M y (4) 7 x ( 2) 5 ¬ y4 7 5 ¬ x 2

x 7 and y 3. slope of M R slope of N P

D C and F G have the same slope, so they are parallel. Since one pair of opposite sides is congruent and parallel, CDFG is a parallelogram. 33.

y6 3 6) ¬1 x ( y6 3 x 6 ¬ 1

y

M

Again, x 7 and y 3. So, move R to (7, 3). 34.

y

Q O x

S

N R

O

P

x

W

Sample answer: Hold N, P, and R fixed. Let M be M(x, y). Find the slopes of M N and M R so that they equal those of P R and N P , respectively. slope of M N slope of P R

T

Hold S, T, and W fixed. Let Q be Q(x, y). Find the slopes of Q S and Q W so that they equal those of W T and S T , respectively. slope of Q S slope of T W

1 y 2 (4) 1 x ¬ 5 (2) 1y 2 1 x ¬ 3

1y 1 (2) 4 x ¬ 5 (1) 1y 1 4 x ¬ 4 1y 1 4 x ¬4

If x 4 and y 1, then M N P R . slope of M R slope of N P 2 y 4 (1) 5 x ¬ 2 (1) 2y 3 5 x ¬1

If x 0 and y 2, then Q S T W . slope of Q W slope of S T

If x 4 and y 1, then M R N P . Move M to (4, 1) to make both pairs of opposite sides parallel. Then MNPR is a parallelogram. Perform the same process for the other vertices. Move N: slope of M N slope of P R

1 y 2 1 5 x ¬ 1 4 1y 3 5 x ¬ 5 1y 3 5 x ¬5

y6 2 6) ¬ x ( 3 y6 2 x 6 ¬3

x 3 and y 4. slope of M R slope of N P

If x 0 and y 2, then Q W S T . Move Q to (0, 2) to make both pairs of opposite sides parallel. Then QSTW is a parallelogram. Perform the same process for the other vertices. Move S: slope of Q S slope of T W

Again, x 3 and y 4. So, move N to (3, 4).

x 1 and y 2. slope of Q W slope of S T

4 y 2 6 2 x 5 (6) ¬ 4 y 8 1 ¬ 2 x

y3 1 3) ¬4 x ( y3 1 x 3 ¬4

2 y 1 3 1 x 5 (3) ¬ 2y 4 ¬ 1x 2

N slope of P R Move P: slope of M 2 y 1 6 5 x 1 (6) ¬ 2y 7 5 ¬ 5x

Again, x 1 and y 2. So, move S to (1, 2).

x 0 and y 9.

253

Chapter 8

Move T: slope of Q S slope of T W

slope of C D slope of A B

1 y 1 3 4 ( 3) ¬ 5 x 1y 2 5 x 7 ¬

y (1) 5 4 x 4 ¬ 71 y1 1 x 4 ¬6

x 2 and y 3. slope of Q W slope of S T

For (10, 0) and (2, 2), C D A B . slope of B C ¬2 Suppose D is (2, 2). 4 (2) D A ¬ slope of 1 (2) ¬2 So D AB C . So, (2, 2), (4, 10), and (10, 0) are the possibilities for the fourth vertex. Any of these values results in both pairs of opposite sides being parallel, and thus, the four points form a parallelogram.

y1 4 ¬ x 4 2 y1 4 ¬ x4 2

Again, x 2 and y 3. So, move T to (2, 3) S slope of T W Move W: slope of Q y (2) 2 x ( 1) 7 ¬ y2 2 ¬ x1 7

Again, x 8 and y 0. slope of Q W slope of S T

36.

y3 2 1 3) ¬ x ( 1 4 y3 3 x 3 ¬ 5

Q R

x 8 and y 0. So, move W to (8, 0). 35.

y

x

O

S

y

B

The fourth vertex can have one of three possible positions to complete the parallelogram. Let T(x, y) be the fourth vertex. Find the slopes of S T and R T so that they equal those of Q R and Q S , respectively. slope of S T slope of Q R

A

x

O

C

y (1) 1 2 x ( 1) ¬ 1 ( 2) y1 1 x 1 ¬3

The fourth vertex can have one of three possible positions to complete the parallelogram. Let D(x, y) be the fourth vertex. Find the slopes of B D and C D so that they equal those of A C and A B , respectively. slope of B D slope of A C

For (2, 2) and (4, 0), S T Q R . 1 2 slope of Q S ¬ 1 (2)

¬3

Suppose T is (2, 2).

y5 1 4 x 7 ¬ 4 1 y5 5 x 7 ¬3

2 1 T ¬ slope of R 21

¬3

For (10, 0) and (4, 10), B D A C . 54 slope of A B ¬

S R T . So Q

1 1 S ¬ slope of R

71 ¬1 6

1 1

¬1

Suppose D is (10, 0).

Suppose T is (4, 0).

0 (1) D ¬ slope of C 10 4 1 ¬ 6

02 T ¬ slope of Q

1 5 C ¬ slope of B 47

T slope of Q S slope of R

4 (2)

¬1 T R S . So Q

So A B C D .

y1 1 2 x 1 ¬ 1 (2) y1 3 x 1 ¬1

¬2

Suppose D is (4, 10). 10 4 D ¬ slope of A 41

¬2 D B C . So A

Chapter 8

254

For (2, 2) and (0, 4), R T Q S . 1 (1) slope of S R ¬ 1 (1) ¬1 Suppose T is (0, 4). 4 2 slope of Q T ¬ 0 (2) ¬1 So S RQ T . So, (2, 2), (4, 0), and (0, 4) are the possibilities for the fourth vertex. Any of these values results in both pairs of opposite sides being parallel, and thus, the four points form a parallelogram. 37. JKLM is a parallelogram because K M and J L are diagonals that bisect each other. 38. If both pairs of opposite sides are parallel and congruent, then the watchbox is a parallelogram. 39. Given: A D B C A B 3 2 B A D C 1 4 Prove: ABCD is a D C parallelogram. Proof: Statements Reasons 1. A D B C , A B D C 2. Draw D B . 3. 4. 5. 6.

DB D B ABD CDB 1 2, 3 4 D A B C , A B D C

7. ABCD is a parallelogram.

41. Given: AB D C B A D C Prove: ABCD is a parallelogram. A

2

D C Proof: Statements

1. Given 2. Two points determine a line. 3. Reflexive Property 4. SSS 5. CPCTC 6. If alternate interior angles are congruent, lines are parallel. 7. Definition of parallelogram

3. 1 2

3. If two lines are parallel, then alternate interior angles are congruent. 4. Reflexive Property 5. SAS 6. CPCTC 7. If both pairs of opposite sides are congruent, then the quadrilateral is a parallelogram.

AC A C ABC CDA D A B C ABCD is a parallelogram.

A

2. Two points determine a line.

D

B

C

43. Given: ABCDEF is a regular hexagon. Prove: FDCA is a parallelogram. A F

B C

E D Proof: Statements

C

1. AE E C , D E E B 2. 1 2 3 4 3. ABE CDE ADE CBE 4. A B D C D A B C 5. ABCD is a parallelogram.

1. Given

42. This theorem is not true. ABCD is a parallelogram with diagonal B D, ABD CBD.

1 3 2 4

Proof: Statements

Reasons

1. A B D C , A B D C 2. Draw A C

4. 5. 6. 7.

40. Given: AE E C , D E E B Prove: ABCD is a parallelogram. A B E D

B

1

1. ABCDEF is a regular hexagon. 2. A B D E , B C E F E B, F A C D 3. ABC DEF 4. A C D F 5. FDCA is a .

Reasons 1. Given 2. Vertical are . 3. SAS 4. CPCTC 5. Definition of parallelogram

Reasons 1. Given 2. Definition of a regular hexagon 3. SAS 4. CPCTC 5. If both pairs of opposite sides are congruent, then the quadrilateral is a parallelogram.

44. Sample answer: The roofs of some covered bridges are parallelograms. The opposite sides are congruent and parallel. Answers should include the following. • We need to know the length of the sides, or the measures of the angles formed. • Sample answer: windows or tiles

255

Chapter 8

45. B;

51. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (135)n ¬180(n 2) 135n ¬180n 360 0 ¬45n 360 360 ¬45n 8 ¬n The polygon has 8 sides. 52. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (144)n ¬180(n 2) 144n ¬180n 360 0 ¬36n 360 360 ¬36n 10 ¬n The polygon has 10 sides. 53. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (168)n ¬180(n 2) 168n ¬180n 360 0 ¬12n 360 360 ¬12n 30 ¬n The polygon has 30 sides. 54. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (162)n ¬180(n 2) 162n ¬180n 360 0 ¬18n 360 360 ¬18n 20 ¬n The polygon has 20 sides. 55. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (175)n ¬180(n 2) 175n ¬180n 360 0 ¬5n 360 360 ¬5n 72 ¬n The polygon has 72 sides. 56. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (175.5)n ¬180(n 2) 175.5n ¬180n 360 0 ¬4.5n 360 360 ¬4.5n 80 ¬n The polygon has 80 sides. 57. The legs of this right triangle have equal lengths, so it is a 45°-45°-90° triangle. The hypotenuse of a 45°-45°-90° triangle is 2 times the length of the legs. Therefore, x 45 and y 12 2. 58. The hypotenuse of this right triangle is twice the length of one of its legs, so it is a 30°-60°-90° triangle. The longer leg is 3 times the length of the shorter leg. Therefore, x 10 3 and y 30.

y

(8, 2)

(2, 2)

x

O ( 1 , 6 )

By plotting choices A, C, and D on the graph, it is obvious that they cannot be the fourth vertex. Choice B is the only possibility. (2, 2) and (8, 2) have the same y-component. These are the endpoints of a horizontal segment 10 units long. (11, 6) and (1, 6) have the same y-component. These are also the endpoints of a horizontal segment 10 units long. These two sides of the quadrilateral are congruent and parallel, so the quadrilateral is a parallelogram. 46. C; use the Distance Formula to find the distance between X and Y. XY ¬ (x x1)2 (y2 y1)2 2 ¬ (3 5)2 (4 7)2 ¬ 185

Page 423 Maintain Your Skills 47. The diagonals of a parallelogram bisect each other, so ML LQ. Find w. ML ¬LQ w ¬12 48. Opposite sides of a parallelogram are congruent, so their measures are equal. Find x. NQ ¬MR 3x 2 ¬4x 2 4 ¬x 49. Opposite sides of a parallelogram are congruent, so their measures are equal. Find x. NQ ¬MR 3x 2 ¬4x 2 4 ¬x So, NQ is 3(4) 2 or 14 units. 50. Opposite sides of a parallelogram are congruent, so their measures are equal. Find y. QR ¬MN 3y ¬2y 5 y ¬5 So, QR is 3(5) or 15 units.

Chapter 8

256

59. Two angles are given, 60° and 90°, so this is a 30°-60°-90° triangle. The shorter leg is half the length of the hypotenuse, and the longer leg is 3 times the length of the shorter leg. Therefore, x 16 3 and y 16. 60. Determine the slopes of A B and B C .

2. Opposite sides of a parallelogram are congruent, so their measures are equal. Find x. WZ ¬XY x2 ¬42 x 0 ¬x2 x 42 0 ¬(x 6)(x 7) 0 x 6 or 0 x 7 6 x 7x x 6 or 7, so x2 36 or 49. So, WZ is 36 or 49. 3. YXZ XZW because they are alternate interior angles. So, mYXZ is 54 and mWXY is 54 60 or 114. WXY and XYZ are supplementary, so mXYZ is 180 114 or 66. 4. Opposite angles of a parallelogram are congruent. Find x and y. 5x 19 ¬3x 9 2x ¬28 x ¬14 6y 57 ¬3y 36 3y ¬93 y ¬31 5. Opposite sides of a parallelogram are congruent. Find x and y. 2x 4 ¬x 4 x ¬8 4y 8 ¬3y 2 y ¬6

y y

2 1 B ¬ slope of A x x 2

1

3 5 ¬ 62 ¬1 2

7 3 slope of B C 86

2 The product of the slopes of A B and B C is 1, so B A B C . 61. Determine the slopes of A B and B C . y y


1

7 2 ¬ 0 (1)

¬5 1 7 slope of B C 40 3 2

The product of the slopes of A B and B C is not 1, so A B is not perpendicular to B C . 62. Determine the slopes of A B and B C . y y


1

7 4 ¬ 50 ¬3 5

8-4

3 7 slope of B C 85 4 3


The product of the slopes of A B and B C is not 1, so A B is not perpendicular to B C . 63. Determine the slopes of A B and B C .

1. If consecutive sides are perpendicular or diagonals are congruent, then the parallelogram is a rectangle. 2. Sample answer:

y y


Rectangles

1

3 (5) ¬ 1 (2) 2 ¬3 0 (3) slope of B C 1 1 3 2

Yes, the opposite sides are congruent and parallel, consecutive sides are perpendicular. 3. McKenna is correct. Consuelo’s definition is correct if one pair of opposite sides is parallel and congruent. 4. The diagonals of a rectangle are congruent, so C A B D . C A ¬B D AC ¬BD 30 x ¬4x 60 90 ¬5x 18 ¬x 5. The diagonals of a rectangle bisect each other and are congruent, so NP 1 P N P . 2 NR and M

The product of the slopes of A B and B C is 1, so B A B C .

Page 423 Practice Quiz 1 1. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2)

147131n ¬180(n 2)

162 0 11 n ¬180n 360 36 0 0 ¬ 11 n 360 36 0 360 ¬ 11 n

NP ¬1 2 NR

2x 30 ¬1 2 (2x 10)

x ¬35 So, MP 2(35) 30 or 40.

11 ¬n The polygon has 11 sides.

257

Chapter 8

6. QRT RTS because they are alternate interior angles. QRT ¬RTS mQRT ¬mRTS x2 1 ¬3x 11 2 x 3x 10 ¬0 (x 5)(x 2) ¬0 x 5 0 or x 2 0 x5 x 2 So, x 5 or 2. 7. QRT and SRT are complementary. mQRT mSRT ¬90 Use the values of x found in Exercise 6. [(2)2 1] mSRT ¬90 5 mSRT ¬90 mSRT ¬85 or 52 1 mSRT ¬90 26 mSRT ¬90 mSRT ¬64 SRT RSQ and the sum of the measures of the interior angles of a triangle is 180. Find mRPS. mRPS mSRT mRSQ ¬180 mRPS 2mSRT ¬180 mRPS 2(64) ¬180 mRPS ¬52 or mRPS 2(85) ¬180 mRPS ¬10 8. The diagonals of a rectangle are congruent. Use the Distance Formula to determine whether the diagonals of quadrilateral EFGH are congruent. EG ¬ (x2 x1)2 (y2 y1)2

11. The diagonals of a rectangle bisect each other, so Q N Q K . Q N ¬Q K Q NQ ¬QK 2x 3 ¬5x 9 12 ¬3x 4 ¬x So, NQ 2(4) 3 or 11. J Q N Q , so JQ 11. 12. Opposite sides of a rectangle are congruent, so K J N M . K J ¬N M JK ¬NM x2 1 ¬8x 14 x2 8x 15 ¬0 (x 3)(x 5) ¬0 x 3 0 or x 5 0 x3 x5 So, x 3 or x 5. JK 32 1 or 10 or JK 52 1 or 26. 13. The sum of the measures of NJM and KJM is 90. Find x. mNJM mKJM ¬90 2x 3 x 5 ¬90 3x ¬88 x ¬291 3 14. KMN is a right triangle, so the sum of the measures of NKM and KNM is 90. Find x. mNKM mKNM ¬90 x2 4 x 30 ¬90 x2 x 56 ¬0 (x 8)(x 7) ¬0 x 8 0 or x 7 0 x 8 x7 So, x 8 or x 7. mKNM 8 30 or 22 or mKNM 7 30 or 37. KNM JKN because they are alternate interior angles, so mJKN 22 or 37. 15. The sum of the measures of JKN and NKM is 90. Find x. mJKN mNKM ¬90 2x2 2 14x ¬90 2x2 14x 88 ¬0 x2 7x 44 ¬0 (x 4)(x 11) ¬0 x 4 0 or x 11 0 x4 x 11 Since mNKM 14x, and the measure of an angle must be positive, discard x 11. So, x 4. 16. m1 30. 17. 2 is complementary to 1 because consecutive sides of a rectangle are perpendicular. So, m2 90 30 or 60. 18. The diagonals of a rectangle are congruent and bisect each other. So, the triangles formed by the diagonals of a rectangle are isosceles. Therefore, 2 3. From Exercise 17, m3 60. 19. 4 is complementary to 3 because consecutive sides of a rectangle are perpendicular. m4 m3 ¬90 m4 60 ¬90 m 4 ¬30

¬ [2 ( 4)]2 [3 (3)]2

¬ 72 HF ¬ (x2 x1)2 (y2 y1)2

¬ [3 ( 5)]2 (1 1)2

¬ 68 The lengths of the diagonals are not equal, so EFGH is not a rectangle. 9. The framer can make sure that the angles measure 90 or that the diagonals are congruent.

Pages 428–430 Practice and Apply 10. The diagonals of a rectangle bisect each other and are congruent, so N Q Q M . Q N ¬Q M NQ ¬QM 5x 3 ¬4x 6 x ¬9 So, NQ 5(9) 3 or 42. NK is twice NQ or 84.

Chapter 8

258

20. 5 1 because they are alternate interior angles. So, m5 30. 21. WXZ is a right triangle, so the sum of the measures of 1 and 6 is 90. Therefore, m6 90 30 or 60. 22. 7 3 because they are alternate interior angles. From Exercise 18, m7 60. 23. 8 is complementary to 7. m8 m7 ¬90 m8 60 ¬90 m8 ¬30 24. The sum of the interior angles of a triangle is 180. m9 m7 m6 ¬180 m9 60 60 ¬180 m 9 ¬60 25. The contractor can measure the opposite sides and the diagonals to make sure they are congruent. 26. Use the Pythagorean Theorem to find the measure of the diagonal of the television screen. 2 b2 c ¬ a 2 ¬ 21 362 441 1296 ¬ 1737 ¬42 The measure of the diagonal is about 42 in. 27. Opposite sides of a rectangle are parallel. Find the slopes of D H and F G . 8

y

F

x 8

4

2

1 ¬ 11

9 8 slope of F G 6 (5) 1 11

9 2 slope of G H 76

11 8 (3)

F slope of D 5 (4) 11 So, D H F G and G H D F . Use the Distance Formula to determine whether the diagonals of quadrilateral DFGH are congruent. DG ¬ (x2 x1)2 (y2 y1)2

D

2 ¬ [6 (4)] [9 (3)]2

8

¬ 244

y2 y1 H slope of D x2 x1 1 (1) ¬ 6 9 2 ¬ 15 y2 y1 slope of F G x2 x1 5 5 ¬ 6 9

FH ¬ (x2 x1)2 (y2 y1)2 ¬ [7 ( 5)]2 (2 8)2 ¬ 244 So, D G F H , D H F G , and G H DF . Therefore, DFGH is a rectangle. 30. Use the Distance y 8 Formula to find WY and XZ. W Z 4

¬0 The slopes are not equal. Therefore, D H and F G are not parallel. So, DFGH is not a rectangle. 28. The diagonals of a rectangle are congruent. Use the Distance Formula to determine whether the diagonals of quadrilateral DFGH are congruent. 8 4

X 8

4

x 4

8

4

Y

8

y

G D

WY ¬ (x2 x1)2 (y2 y1)2

H

¬ (1 2)2 (7 4)2 ¬ 130

x 4 4

1

2 (3)

¬ 7 (4)

8

4

H y y

x O

8

4

2 1 slope of D H x x

4 4

4

D 4

y

H

G

8 4

F

G 8

To determine if DFGH is a rectangle, the points must be connected in the order given. When the points are plotted and connected, it is clear that DFGH is not a quadrilateral. So DFGH is not a rectangle. 29. If the opposite sides of a quadrilateral are parallel and the diagonals of the quadrilateral are congruent, then the quadrilateral is a rectangle. H , F G , G H , and D F . Find the slopes of D

F

12

XZ ¬ (x x1)2 (y2 y1)2 2

8

¬ (3 0 )2 [9 (2 )]2 ¬ 130

259

Chapter 8

So by transitivity of parallel lines and substitution, H G E F and HG EF. So GHEF is a parallelogram. Since H and E are midpoints, by (BD) the Triangle Midsegment Theorem, HE 1 2

31. See the figure in Exercise 30. Find the coordinates of the midpoints of W Y and X Z .

x x

y y

2 (1)

4 (7)

1 2 1 2 Y W : 2, 2 2 , 2

3 1 2, 2 x1 x2 y1 y2 3 2 9 0 Z X : 2 , 2 2 , 2

(BD). Since AC BD, HE 1(AC) and GF 1 2 2 and GF 21(AC). Therefore, HE GH GF EF. EFGH is a parallelogram with all sides congruent. 35. To make the diagonals the same, either A C must be shortened or B D must be lengthened. This can be accomplished by moving L and K until the length of the diagonals is the same. 36. Find the ratio of the length to the width of the rectangle.

3 7 2, 2 32. The midpoints of the diagonals are not the same (Exercise 31), so the diagonals do not bisect each other. Therefore, WXYZ is not a rectangle.

33. Consecutive sides of a rectangle are perpendicular. Find the slopes of A B , B C , C D , and A D .

19. 42 12.01 1.617

Since 1.617 is close to 1.618, the rectangle is a golden rectangle. Use the Pythagorean Theorem to find the length of the diagonal. 2 b2 c a 19.422 12.01 2 22.83 The length of the diagonal is about 22.83 ft. 37. See students’ work. 38. Parallelograms have opposite sides congruent and bisecting diagonals, so the minimal requirements to justify that a parallelogram is a rectangle are that diagonals are congruent or the parallelogram has one right angle. 39. Sample answer: A B

y

C D

x O

B A y y

2 1 B slope of A x x 2

1

1 (4)

2 ( 4) 1 2 3 (1)

slope of B C 02

2

D

03 D slope of C 6 0 1 2

4 0 slope of D A 4 (6)

2 The consecutive sides are perpendicular. Therefore, ABCD is a rectangle. 34.

X W Proof:

y

C

Statements

G F D

O

Y Z Reasons

1. WXYZ is a rectangle 1. Given with diagonals W Y and X Z . 2. W X Z Y 2. Opp. sides of are . 3. Reflexive Property 3. W Z W Z 4. Def. of rectangle 4. XWZ and YZW are right angles 5. All right are . 5. XWZ YZW 6. SAS 6. XWZ YZW 7. CPCTC 7. W Y X Z

x

B H E A Draw diagonals A C and B D . ABCD is a rectangle. So A C B D and AC BD. Since G and H are midpoints, by the Triangle Midsegment Theorem G H A C and HG 1 2 (AC)

Since E and F are midpoints, F E A C and EF 1 2 (AC)

Chapter 8

C

AC B D but ABCD is not a rectangle. 40. Given: WXYZ is a rectangle with diagonals W Y and X Z . Prove: W Y X Z

260

41. Given: W X Y Z , X Y W Z , and W Y X Z Prove: WXYZ is a rectangle. W

X

Z

Y

43. Given: DEAC and FEAB are rectangles. GKH JHK G J and H K intersect at L. Prove: GHJK is a parallelogram.

1. WX Y Z, X Y W Z , and W Y X Z 2. W X W X 3. WZX XYW 4. ZWX YXW 5. mZWX mYXW 6. WXYZ is a parallelogram 7. ZWX and YXW are supplementary 8. mZWX mYXW 180 9. ZWX and YXW are right angles

Reasons

BC

1. Given

K

Reflexive Property SSS CPCTC Def. of Def. of parallelogram

S

P

V

T

L

H Reasons

1. DEAC and FEAB are rectangles. GKH JHK G J and H K intersect at L. 2. D E A C and E F A B 3. plane plane 4. G, J, H, K, L are in the same plane. 5. G H K J 6. K G H J 7. GHJK is a parallelogram.

7. Consec. of are suppl. 8. Def. of suppl.

Prove: P R V S R

D G

Proof: Statements

42. Given: PQST is a rectangle. R Q V T Q

E

F

J 2. 3. 4. 5. 6.

9. If 2 are and suppl., each is a rt. . 10. WXYZ is a rectangle 10. Def. of rectangle

Proof: Statements

N

MA

Proof: Statements

1. Given

2. Def. of parallelogram 3. Def. of parallel plane 4. Def. of intersecting lines 5. Def. of parallel lines. 6. Alt. int. are . 7. Def. of parallelogram

44. Explore: We need to find the number of rectangles that can be formed using four of the twelve points as corners. Plan: Count the number of rectangles with each possible set of dimensions. Arrange the data in a table Solve: Dimensions Number length width of rectangles

Reasons

1. PQST is a rectangle. 1. Given R Q V T 2. PQST is a 2. Def. of rectangle parallelogram. 3. T S P Q 3. Opp. sides of are . 4. Definition of 4. T and Q are rectangle rt. s. 5. All rt. are . 5. T Q 6. SAS 6. RPQ VST 7. CPCTC 7. P R V S

32

1

31

2

22

2

21

4

12

3

11

6

There are 18 rectangles formed by using the rows and columns as sides. There are 2 additional rectangles formed as shown.

Examine: The table covers all possible dimensions. The figure shows the only rectangles that can be formed using rectangles at an angle to the rows and columns. So the answer is reasonable.

261

Chapter 8

45. No; there are no parallel lines in spherical geometry.

57. Opposite sides of a parallelogram are congruent, so their measures are equal. Find x. AB ¬CD 5x ¬25 x ¬5

46. AC appears to be shorter than TR, so AC TR. 47. Since the sides would not be parallel in spherical geometry, a rectangle cannot exist.

58. ST is the altitude to side Q R in right triangle QSR so by Theorem 7.2, its measure is the geometric mean between the two segments of the hypotenuse. Let x ST.

48. Sample answer: The tennis court is divided into rectangular sections. The players use the rectangles to establish the playing area. Answers should include the following.

18 x x ¬ 34

• Not counting overlap, there are 5 rectangles on each side of a tennis court.

x2 ¬612

• Measure each diagonal to make sure they are the same length and measure each angle to make sure they measure 90.

x ¬ 612 x ¬24.7 59. NP is the altitude to side M O in right triangle MNO so by Theorem 7.2, its measure is the geometric mean between the two segments of the hypotenuse. Let x NP.

49. A; since A B C E , ADE BAD and BDC ABD because they are alternate interior angles. It is given that ADE BAD, so BAD ABD. Therefore, ABD is isosceles and DB DA, so DB is 6.

11 x x ¬ 2 7

50. D; since s is the shorter side of the playground, s 10 is the longer side. The perimeter of the fence is 80 feet, and the perimeter of a rectangle is equal to twice the width plus twice the length. Therefore, the equation to find s is 2(s 10) 2s 80.

x2 ¬297 x ¬ 297 x ¬17.2 60. The measure of the altitude to A B is the geometric mean between the two segments of the hypotenuse of ABC. Let x the measure of the altitude.


24 x x ¬ 1 4

51. There are 31 parallelograms: 11 individual parallelograms, 12 using two others, 6 using three others, and 2 using four others.

x2 ¬336 x ¬ 336 x ¬18.3

52. The sum of the measures of the internal angles of a triangle is 180. Find mAFD.

61. Use the Distance Formula to find the distance betweeen the given points.

mAFD mFDA mDAF ¬180 mAFD 34 49 ¬180 mAFD ¬97

d ¬ (x2 x1)2 (y2 y1)2 ¬ (3 1)2 [1 (2)] 2

53. ACD BAC because they are alternate interior angles. mACD 54. So, mBAC 54. BAD is supplementary to ADC. Find mCDF. mCDF mFDA mDAF mBAC ¬180 mCDF 34 49 54 ¬180 mCDF ¬43

¬5 The distance between the points is 5 units. 62. Use the Distance Formula to find the distance between the given points. d ¬ (x2 x1)2 (y2 y1)2

54. FBC ADF because they are alternate interior angles. mADF 34. So, mFBC 34.

¬ [5 ( 5)]2 (12 9)2 ¬ 109

55. BCF DAF because they are alternate interior angles. mDAF 49. So, mBCF 49.

¬10.4 The distance between the points is 109 or about 10.4 units.

56. Opposite sides of a parallelogram are congruent, so their measures are equal. Find y. BC ¬AD 3y 4 ¬29 3y ¬33 y ¬11

63. Use the Distance Formula to find the distance between the given points. d ¬ (x2 x1)2 (y2 y1)2 ¬ (22 1)2 (24 4)2 ¬29 The distance between the points is 29 units.

Chapter 8

262

QM ¬ (3 0 )2 (0 3)2

Rhombi and Squares

8-5

¬ 9 9 ¬3 2 Use slope to determine whether the consecutive sides are perpendicular.


03 N slope of M 3 0

1. Sample answer:

1

Square (rectangle with 4 sides) Rectangle ( with 1 right )

3 0 P slope of N 0 ( 3)

1

0 3 Q slope of P 03

Rhombus ( with 4 sides)

1

0 3 slope of Q M 30

1

Parallelogram (opposite sides || )

N and P Q are opposite Since the slopes of M reciprocals of the slopes of N P and Q M , consecutive sides are perpendicular. The lengths of the four sides are the same, so the sides are congruent. MNPQ is a rectangle, a rhombus, and a square.

2. Sample answer:

9.

3. A square is a rectangle with all sides congruent. 4. The sides of a rhombus are congruent. Find x. AB ¬BC 2x 3 ¬5x 3 ¬3x 1 ¬x The value of x is 1.

P

M

x

O

Q

5. From Exercise 1, x 1. So, BC 5(1) or 5. AD is congruent to BC, so AD 5.

If the diagonals are congruent, then parallelogram MNPQ is either a rectangle or a square. If the diagonals are perpendicular, then MNPQ is a square or a rhombus. Use the distance formula to compare the lengths of the diagonals.

6. The diagonals of a rhombus are perpendicular, so mAEB 90. 7. Consecutive angles of a rhombus are supplementary. Find mBCD. mBCD mABC ¬180 mBCD 83.2 ¬180 mBCD ¬96.8 8.

y

N

MP (4 2)2 (0 2)2 36 4 40 NQ (3 1)2 [3 (1)] 2

y

M

16 16 32 Use slope to determine whether the diagonals are perpendicular.

N

02 P slope of M 4 2

Q x

O

1 3

1 3 slope of N Q 1 ( 3)

P

1

If the four sides are congruent, then parallelogram MNPQ is either a rhombus or a square. If consecutive sides are perpendicular, then MNPQ is a rectangle or a square. Use the distance formula to compare the lengths of the sides.

The diagonals are not congruent or perpendicular. MNPQ is not a rhombus, a rectangle, or a square.

MN ¬ (3 0)2 (0 3 )2 ¬ 9 9 3 2 2 NP ¬ [0 (3)] (3 0)2

¬ 9 9 3 2 2 [03)] PQ ¬ [3 ] 0 (2

¬ 9 9 3 2

263

Chapter 8

10. Given: KGH, HJK, GHJ, and JKG are isosceles. Prove: GHJK is a rhombus. G H

16. The diagonals of a rhombus are perpendicular, so mYVZ 90. The measure of the interior angles of a triangle is 180. Find mYZV. mYVZ mYZV mWYZ ¬180 90 mYZV 53 ¬180 mYZV 143 ¬180

K

mYZV ¬37

J

17. The diagonals of a rhombus bisect the angles, so XYW WYZ and mXYW 53.

Proof: Statements

Reasons

1. KGH, HJK, GHJ, and JKG are isosceles. 2. K G G H , H J K J , H G H J , K G K J 3. K G H J , G H K J 4. K G G H , H J K J 5. GHJK is a rhombus.

18. The diagonals of a rhombus bisect each other, so V X Z V . Find a.

1. Given

V X ¬Z V XV ¬ZV

2. Def. of isosceles

5a 1 2a 2 ¬ 4

8a 8 ¬5a 1

3. Transitive Property 4. Substitution 5. Def. of rhombus

3a ¬9 a ¬3 So, XV 2(3) 2 or 4 and XZ is twice XV or 8. 19. From Exercise 18, XV 4. VW 3. The diagonals of a rhombus are perpendicular, so mWVX 90 and WVX is a right triangle. W X is the hypotenuse of WVX. Use the Pythagorean Theorem. (VW)2 (XV)2 ¬(XW)2 32 42 ¬(XW)2 25 ¬(XW)2 5 ¬XW 20. y

11. If the measure of each angle is 90 or if the diagonals are congruent, then the floor is a square.

Pages 434–437

Practice and Apply

12. Consecutive angles in a rhombus are supplementary, so DAB and ADC are supplementary. Find mDAB. mDAB mADC ¬180 mDAB 1 2 mDAB ¬180

12

3 mDAB ¬180 2

8

mDAB ¬120 Opposite angles of a rhombus are congruent, so BCD DAB. The diagonals of a rhombus

4

F

bisect the angles, so mACD 1 2 mBCD or 60.

4

13. Consecutive angles in a rhombus are supplementary, so DAB and ADC are supplementary. Find mDAB.

G O

4

8

12 x

If the diagonals are congruent, then parallelogram EFGH is either a rectangle or a square. If the diagonals are perpendicular, then EFGH is a square or a rhombus. Use the Distance Formula to compare the lengths of the diagonals. EG ¬ (1 7 )2 (1 0 2)2 ¬ 36 6 4 100 ¬10 FH ¬ (4 12)2 (0 12) 2 ¬ 256 144 400 ¬20 Use slope to determine whether the diagonals are perpendicular. 2 10 slope of E G ¬ 17

mDAB mADC ¬180 mDAB 1 2 mDAB ¬180 3 mDAB ¬180 2

mDAB ¬120 14. By definition, a rhombus has four congruent sides, so D A C B and DA 6. 15. Consecutive angles in a rhombus are supplementary, so DAB and ADC are supplementary. Find mADC. mDAB mADC ¬180 2(mADC) mADC ¬180

¬4 3

3(mADC) ¬180

0 12 slope of F H ¬ 4 12

mADC ¬60 The diagonals of a rhombus bisect the angles, so

3 4

mADB 1 2 (mADC) or 30.

Chapter 8

H E

264

The diagonals are not congruent. Since the slopes of E G and F H are opposite reciprocals of each other, the diagonals are perpendicular. EFGH is a rhombus. 21.

23.

y G

F H

y G

H

O

x

E F

E

O

If the diagonals are congruent, then parallelogram EFGH is either a rectangle or a square. If the diagonals are perpendicular, then EFGH is a square or a rhombus. Use the Distance Formula to compare the lengths of the diagonals. EG ¬ (2 1)2 (1 5)2 ¬ 9 36 45 FH ¬ (4 3)2 (3 1 )2 ¬ 49 4 53 Use slope to determine whether the diagonals are perpendicular.

x

If the diagonals are congruent, then parallelogram EFGH is either a rectangle or a square. If the diagonals are perpendicular, then EFGH is a square or a rhombus. Use the Distance Formula to compare the lengths of the diagonals. EG ¬ (7 1)2 (3 7 )2 ¬ 64 1 6 80 2 (3 FH ¬ [2 (4)] 7)2 ¬ 4 16 20 Use slope to determine whether the diagonals are perpendicular. 37 slope of E G ¬ 7 1

1 5 G ¬ slope of E 2 1

¬2

31 H ¬ slope of F 4 3 ¬2 7

¬1 2 37 slope of F H ¬ 2 (4) ¬2 The diagonals are not congruent. Since the slopes of E G and F H are opposite reciprocals of each other, the diagonals are perpendicular. EFGH is a rhombus.

22.

y H

G

E

F

The diagonals are not congruent or perpendicular. EFGH is not a rhombus, a rectangle, or a square. 24. Sample answer:

3 cm 3 cm

25. Sample answer:

5 cm

O

26. Every square is a parallelogram, but not every parallelogram is a square. The statement is sometimes true. 27. Every square is a rhombus. The statement is always true. 28. Every rectangle is a parallelogram. The statement is always true. 29. If a rhombus is a square, then the rhombus is also a rectangle. Otherwise the rhombus is not a rectangle. The statement is sometimes true. 30. Every square is a rhombus, but not every rhombus is a square. The statement is sometimes true. 31. Every square is a rectangle. The statement is always true.

x

If the four sides are congruent, then parallelogram EFGH is either a rhombus or a square. If consecutive sides are perpendicular, then EFGH is a rectangle or a square. It is obvious from the figure that each side has measure 5, so the sides are congruent. It is also obvious that H E and G F are vertical segments and H G and E F are horizontal, so consecutive sides are perpendicular. Thus, EFGH is a square, a rectangle, and a rhombus.

265

Chapter 8

32. The width of the square base is 153 4 in. Since the width of the smaller boxes is one half the width of the square base, the dimensions of the smaller 7 boxes are 77 8 in. by 7 8 in.

37. The width and length of the rectangular court are 6400 mm and 9750 mm, respectively. The measure of the diagonal can be found using the Pythagorean Theorem with width and length as the legs of a right triangle. diagonal measure 6400 2 9750 2 ¬11,662.9 No; the diagram is not correct. The correct measure is about 11,662.9 mm. 38. The side length of the square service boxes is 1600 mm. The length of the diagonal can be found using the Pythagorean Theorem with the side length of the square service boxes as the legs of a right triangle. diagonal length 16002 160 02 ¬2263 The length of the diagonal of the square service boxes is about 2263 mm or 2.263 m. 39. The flag of Denmark contains four red rectangles. The flag of St. Vincent and the Grenadines contains a blue rectangle, a green rectangle, a yellow rectangle, a blue and yellow rectangle, a yellow and green rectangle, and three green rhombi. The flag of Trinidad and Tobago contains two white parallelograms and one black parallelogram. 40. Given: WZY WXY WZY and XYZ are isosceles. Prove: WXYZ is a rhombus.

33. The diagonals of a rhombus bisect each other and are perpendicular, so along with the sides, they 12 form four congruent right triangles with legs 2 1 6 or 6 cm and 2 or 8 cm. Find the length of one of the four congruent sides–the hypotenuse of one of the right triangles–by using the Pythagorean Theorem. side length ¬ 62 82 ¬ 36 6 4 10 The side length is 10 cm, so the perimeter of the rhombus is 4(10) or 40 cm. 34. ABCD is a rhombus; EFGH and JKLM are congruent squares. 35. Given: ABCD is a parallelogram. C A B D Prove: ABCD is a rhombus. A B E

D

C

Proof: We are given that ABCD is a parallelogram. The diagonals of a parallelogram bisect each other, so A E E C . B E B E because congruence of segments is reflexive. We are also given that A C B D . Thus, AEB and BEC are right angles by the definition of perpendicular lines. Then AEB BEC because all right angles are congruent. Therefore, AEB CEB by SAS. A B B C by CPCTC. Opposite sides of parallelograms are congruent, so A B C D and C B A D . Then since congruence of segments is transitive, A B C D B C A D . All four sides of ABCD are congruent, so ABCD is a rhombus by definition. 36. Given: ABCD is a rhombus. Prove: Each diagonal bisects a pair of opposite angles. A B 6 5 1 2

D

3

W P Z

Z W X , Z Y X Y 2. W

2. CPCTC

Z Z Y , W X X Y 3. W

3. Def. of isosceles triangle

4. W Z W X Z Y X Y 4. Substitution Property 5. WXYZ is rhombus.

5. Def. of rhombus

41. Given: TPX QPX QRX TRX Prove: TPQR is a rhombus. P Q

8

C

Proof: We are given that ABCD is a rhombus. By definition of rhombus, ABCD is a parallelogram. Opposite angles of a parallelogram are congruent, so ABC ADC and BAD BCD. B A B C C D D A because all sides of a rhombus are congruent. ABC ADC by SAS. 5 6 and 7 8 by CPCTC. BAD BCD by SAS. 1 2 and 3 4 by CPCTC. By definition of angle bisector, each diagonal bisects a pair of opposite angles.

Chapter 8

Y

Proof: Statements Reasons 1. Given 1. WZY WXY WZY and XYZ are isosceles.

4 7

X

X T

R

Proof: Statements 1. TPX QPX QRX TRX

266

Reasons 1. Given

2. T P P Q Q R T R

2. CPCTC

3. TPQR is a rhombus.

3. Def. of rhombus

42. Given: LGK MJK GHJK is a parallelogram. Prove: GHJK is a rhombus. J K

• Sample answer: Since the angles of a rhombus are not all congruent, riding over the same road would not be smooth. 46. B; the side length of the square is 36 6 units. So, the perimeter of the square is 4(6) or 24 units. Since rectangle ABCD is contained within the square, which itself is a rectangle, ABCD cannot have a greater perimeter than the square. Therefore, the perimeter of rectangle ABCD is less than 24 units. 47. C; test all four values.

M L H

G

Proof: Statements Reasons 1. Given 1. LGK MJK GHJK is a parallelogram. 2. K G K J

2. CPCTC

3. K J G H , K G J H

0

3. Opp. sides of are .

1 x x2 1 2

4. K G J H G H J K

4. Substitution Property 5. Def. of rhombus

1

3

2 4

4

5 21 2 2

5. GHJK is a rhombus.

x

3 has the greatest value.

43. Given: QRST and QRTV are rhombi. Prove: QRT is equilateral. Q R V

T

Pae 437

S

Proof: Statements 1. QRST and QRTV are rhombi. V V T T R Q R , 2. Q T Q T S R S Q R

Reasons 1. Given 2. Def. of rhombus

3. Q T T R Q R

3. Substitution Property

4. QRT is equilateral.

4. Def. of equilateral triangle


48. The diagonals of a rectangle bisect each other and are congruent, so P J L J . J P ¬L J PJ ¬LJ 3x 1 ¬2x 1 x ¬2 So, x 2. 49. The interior angles of a rectangle are 90°. Find mMLK. mMLK mPLM ¬mPLK mMLK 90 ¬110 mMLK ¬20 Diagonals of a rectangle are congruent and bisect each other. So J L J M . Then LKMJ is a rhombus because opposite sides of a parallelogram are congruent. Since each diagonal of a rhombus bisects a pair of congruent opposite angles, KML MLK. The sum of the measures of the interior angles of a triangle is 180. Find mLKM. mMLK mLKM mKML ¬180 20 mLKM 20 ¬180 mLKM ¬140 So, mLKM 140. 50. MJN is supplementary to PJN. Find mPJN. mMJN mPJN ¬180 35 mPJN ¬180 mPJN ¬145 Since the diagonals of a rectangle are congruent and bisect each other, PJN is isosceles with sides P J and J N congruent. Since PJN is isosceles, MPN PNL. The sum of the measures of the interior angles of a triangle is 180. Find mMPN. mMPN mPNL mPJN ¬180 mMPN mMPN 145 ¬180 2(mMPN) ¬35 mMPN ¬17.5 So, mMPN 17.5.

44. Hexagons 1, 2, 3, and 4 have 3, 12, 27, and 48 rhombi, respectively. Note that the numbers of rhombi are 3 3(1) 3(12), 12 3(4) 3(22), 27 3(9) 3(32), and 48 3(16) 3(42). So, the number of rhombi are given by 3x2, where x is the hexagon number. Number of Hexagon rhombi 1 3 2 12 3 27 4 48 5 75 6 108 x 3x2 45. Sample answer: You can ride a bicycle with square wheels over a curved road. Answers should include the following. • Rhombi and squares both have all four sides congruent, but the diagonals of a square are congruent. A square has four right angles and rhombi have each pair of opposite angles congruent, but not all angles are necessarily congruent.

267

Chapter 8

51. Since the diagonals of a rectangle are congruent and bisect each other, L J J N . Since the sides of a rhombus are congruent, L J M K . Therefore, K M J N . Find x. K M ¬J N MK ¬JN 6x ¬14 x 7x ¬14 x ¬2 Once again, the sides of a rhombus are congruent, K K L . Find y. so M K M ¬K L MK ¬KL 6x ¬3x 2y 3x ¬y 2 Substituting the value of x from above,

54. No; y

H J G x

F

If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent. HJ ¬ (3 2)2 (4 1 )2 ¬ 34 2 FG ¬ [1 (4)] (1 1)2 ¬ 29 Since HJ FG, H J F G . Therefore, FGHJ is not a parallelogram. 55. No;

3(2) ¬y 2

3 ¬y So, x 2 and y 3. 52. Since mLMP mPMN, the diagonal P M bisects LMN. If the diagonals of a rectangle bisect its interior angles, the rectangle must be a square. The diagonals of a square are perpendicular, so mPJL 90. 53. Yes; y

8

M

4

L

N

Q

8

4

4

K R

8

x

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram. The slope of N K is undefined, since it is vertical. L M is clearly not vertical. The opposite sides, K N and L M , do not have the same slope, so they are not parallel. Therefore, KLMN is not a parallelogram. 56. Yes;

S

If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent. 2 (2 PQ ¬ (0 6) 4)2 ¬ 40 RS ¬ [4 ( 2)]2 [0 (2)]2 ¬ 40 2 (4 QR ¬ (6 4) 0)2 ¬ 20 PS ¬ [0 ( 2)]2 [2 (2)]2 ¬ 20 Since the measures of both pairs of opposite sides are equal, PQRS is a parallelogram.

8

y

C

4 8

D

A

4

8x

B 8

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram. 1 (5) B ¬ slope of A 4 (2)

¬2

7 3 D ¬ slope of C 13

¬2

1 7 C ¬ slope of A 4 1 ¬8 5

5 3 slope of B D ¬ 2 3 ¬8 5

Chapter 8

8x

4

P O

y

268

Since opposite sides have the same slope, A B C D and A C B D . Therefore, ABDC is a parallelogram by definition. 57. From the Triangle Proportionality Theorem,

Page 438 Geometry Activity: Kites 1. 2. 3. 4.

QP PS . ST RT

Substitute the known measures.

The diagonals intersect at a right angle. QRS QTS See students’ work; N R T N , but Q N N S . 3 pairs: QRN QTN, RNS TNS, QRS QTS

5.

PS 24 9 ¬ 16

PS(16) ¬24(9) 16(PS) ¬216 PS ¬13.5 58. From the Triangle Proportionality Theorem, QS PS . PT QR Substitute the known measures.

J K

P

M

L The diagonals intersect in a right angle; JKL JML; K P P M , J P P L ; 3 pairs: JPK JPM, KPL MPL, JKL JML. 6. One pair of opposite angles is congruent. The diagonals are perpendicular. The longer diagonal bisects the shorter diagonal. The short sides are congruent and the long sides are congruent.

y2 16 ¬ 16 12 y3

4(y 2) ¬16(y 3) 4y 8 ¬16y 48 56 ¬12y 42 3 ¬y 59. From the Triangle Proportionality Theorem, RT T S PS QP .

Trapezoids

8-6

Substitute the known measures. T S 15 TS 8 ¬ 21

60. 61. 62. 63. 64.

Page 441 Geometry Activity: Median of a Trapezoid

21(TS) ¬15(TS 8) 6(TS) ¬120 TS ¬20 If A G A C , ACG is isosceles. Then AGC ACG. If A J A H , AJH is isosceles. Then AJH AHJ. If AFD ADF, ADF is isosceles. Then A F D A . If AKB ABK, ABK is isosceles. Then A K B A . Solve for x.

1. See students’ work. 2. The median is the average of the lengths of the bases. So, MN 1 2 (WX ZY).

Page 442 Check for Understanding 1. Exactly one pair of opposite sides is parallel. 2. Properties Trapezoid Rectangle Square Rhombus diagonals are only congruent

1 (8x 6x 7) ¬5 2

diagonals are

8x 6x 7 ¬10 2x ¬17 x ¬8.5 65. Solve for x. 1(7x 3x 1) ¬12.5 2 7x 3x 1 ¬25 10x ¬24 x ¬2.4 66. Solve for x. 1(4x 6 2x 13) ¬15.5 2 4x 6 2x 13 ¬31 6x ¬12 x ¬2 67. Solve for x. 1(7x 2 3x 3) ¬25.5 2 7x 2 3x 3 ¬51 10x ¬50 x ¬5

perpendicular

yes

yes

no

no

no

yes

yes

no

yes

yes

yes

no

no

yes

yes

isosceles

diagonals bisect each other diagonals bisect angles

3. Sample answer: The median of a trapezoid is parallel to both bases.

trapezoid

isosceles trapezoid

269

Chapter 8

4.

8. The perspective makes it appear that the buildings are formed by trapezoids and parallelograms.

y

R

S

Q


T

9a.

y

x

D

A A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 2 2 slope of Q T ¬ 3 6 ¬0 6 6 slope of R S ¬ 1 4 ¬0 2 6 slope of Q R ¬ 3 (1) ¬2 6 2 slope of S T ¬ 46 ¬2 Exactly one pair of opposite sides is parallel, Q T and R S . So, QRST is a trapezoid. 5. See graph in Exercise 4. Use the Distance Formula to show that the legs are congruent. QR ¬ [3 (1)]2 (2 6)2 ¬ 4 16 20 ST ¬ (4 6 )2 (6 2)2 ¬ 4 16 20 Since the legs are congruent, QRST is an isosceles trapezoid. 6. Given: CDFG is an isosceles D C trapezoid with bases D C and F G . Prove: DGF CFG G F Proof: CDFG is an isosceles trapezoid with bases CD and GF.

CG

x O

A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 3 3 slope of A D ¬ 3 2 ¬0

1 (1) C ¬ slope of B 4 5

¬0 3 (1) slope of A B ¬ 3 (4) ¬4

3 1 D ¬ slope of C 52 ¬4 3 Exactly one pair of opposite sides is parallel, A D and B C . So, ABCD is a trapezoid. 9b. y

x O

B

DF

DG

GF

GF

Reflex. Prop.

CGF

DFG

SSS

DGF

CFG

CPCTC

7. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find x. YZ ¬1 2 (EF HG) 13 ¬1 2 [(3x 8) (4x 10)] 26 ¬7x 2 28 ¬7x 4 ¬x

Chapter 8

C

Use the Distance Formula to determine whether the legs are congruent. AB ¬ [3 (4)]2 [3 ( 1)]2 ¬ 1 16 ¬ 17 CD ¬ (5 2 )2 ( 1 3)2 ¬ 9 16 ¬5 Since the legs are not congruent, ABCD is not an isosceles trapezoid.

Def. isos. trap.

Diag. of isos. trap. are .

D

A

Given

CF

C

B

270

10a.

0 ( 10) E ¬ slope of F 6 (4) ¬1 3 (10) slope of D E ¬ 5 (4)

J y

H

¬7

K

10 F ¬ slope of C 1 6

x O

¬1 7 Exactly one pair of opposite sides is parallel, D C and F E . So, CDEF is a trapezoid. 11b. 8 y

G A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 4 4 H ¬ slope of G 5 5

4

C

¬4 5

D

5 1 slope of K J ¬ 0 (5) ¬4 5 1 (4) slope of G K ¬ 5 (5) 5 ¬0 or undefined 4 5 slope of H J ¬ 50 1 ¬5

4

E Use the Distance Formula to show that the legs are congruent. 2 [ DE ¬ [5 (4)] 3 (10)] 2 ¬ 1 49 ¬ 50 CF ¬ (1 6)2 (1 0)2 ¬ 49 1 ¬ 50 Since the legs are congruent, CDEF is an isosceles trapezoid. 12a. y

H

K

8x

4

8

Exactly one pair of opposite sides is parallel, K J and G H . So, GHJK is a trapezoid. 10b. J y

F O

8 4

x O

8

R S

G

4

Q

Use the Distance Formula to determine whether the legs are congruent. GK ¬ [5 (5)]2 ( 4 1)2 ¬ 0 25 ¬5 2 (5 JH ¬ (0 5) 4)2 ¬ 25 1 ¬ 26 Since the legs are not congruent, GHJK is not an isosceles trapezoid. 11a. 8 y

8

A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 14 slope of Q R ¬ 12 (9) ¬1 4 3 slope of T S ¬ 11 (4) ¬1 1 (4) slope of Q T ¬ 12 (11)

D

¬5

F O

8 4

4

O x 4

T

4

C

8 4

12

43 S ¬ slope of R 9 (4)

8x

¬1 5 Exactly one pair of opposite sides is parallel, Q R and T S . So, QRST is a trapezoid.

4 8

E A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 3 1 C ¬ slope of D 5 (1) ¬1

271

Chapter 8

12b. 8

R S

So, AB 16. Q and S are supplementary to T and R, respectively. So, mQ 180 120 or 60 and mS 180 45 or 135. 17. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. First find AB. AB ¬1 2 (RS QT)

y

4

Q O x

8 4

12

T

4 8

¬1 2 (54 86) ¬70 So, AB 70. Find GH. GH ¬1 2 (RS AB)

Use the Distance Formula to show that the legs are congruent. 2 QT ¬ [1 (4)] [1 2 (11)] 2 ¬ 25 1 ¬ 26 RS ¬ (4 3 )2 [ 9 ( 4)]2 ¬ 1 25 ¬ 26 Since the legs are congruent, QRST is an isosceles trapezoid. 13. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find DE. XY ¬1 2 (DE HG)

¬1 2 (54 70)

¬62 So, GH 62. 18. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find AB. From Exercise 17, AB 70. Find JK. JK ¬1 2 (QT AB)

20 ¬1 2 (DE 32)

¬1 2 (86 70)

40 ¬DE 32 8 ¬DE 14. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find VT. AB ¬1 2 (VT RS)

¬78 So, JK 78. 19. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find RP. RP ¬1 2 (JK LM)

15 ¬1 2 (VT 26)

10 2x ¬2x 6 1 2x 1 1 5 ¬2x

10 ¬x x 10, so RP 5 10 or 15. 20. Since the two octagons are regular polygons with the same center, the quadrilaterals are trapezoids with one pair of opposite sides parallel. 21. Sample answer: triangles, quadrilaterals, trapezoids, hexagons 22. A trapezoid must have exactly one pair of opposite sides parallel. A parallelogram must have both pairs of opposite sides parallel. A square must have all four sides congruent and consecutive sides perpendicular. A rhombus must have all four sides congruent. A quadrilateral has four sides. Use the Slope Formula to determine whether the opposite sides are parallel. 2 4 slope of B C ¬ 14

¬1 2 (8 20) ¬14 The length of the median is 14. Both base pairs of an isosceles trapezoid are congruent, so mX 70 and mW mZ. The sum of the measures of the interior angles of a quadrilateral is 360. Find mW and mZ. mW mZ mX mY ¬360 mW mW 70 70 ¬360 2(mW) ¬220 mW ¬110 mZ ¬110 16. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find AB. AB ¬1 2 (TS QR)

¬2 3

1) 1 ( slope of D E ¬ 52 ¬2 3

4 1 slope of C D ¬ 45

¬1 2 (12 20)

¬3

¬16 Chapter 8

1 5 x ¬1 2 2(x 3) 2 x 1

30 ¬VT 26 4 ¬VT 15. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find the length of the median and let it be x. x ¬1 2 (WZ XY)

272

1) 2 ( slope of B E ¬ 12

1 (2) slope of M P ¬ 3 (2)

¬3 Use the distance formula to compare the lengths of the sides. BC ¬ (1 4 )2 (2 4)2 ¬ 94 ¬ 13 2 [1 DE ¬ (5 2) ( 1)]2 ¬ 94 ¬ 13 CD ¬ (4 5 )2 (4 1)2 ¬ 19 ¬ 10 BE ¬ (1 2 )2 [2 (1)] 2 ¬ 19 ¬ 10 Opposite sides are parallel. Since the slopes of consecutive sides are not negative reciprocals, consecutive sides are not perpendicular; there are no right angles. Opposite sides are congruent, but consecutive sides are not congruent. BCDE is a parallelogram. 23. A trapezoid must have exactly one pair of opposite sides parallel. A parallelogram must have both pairs of opposite sides parallel. A square must have all four sides congruent and consecutive sides perpendicular. A rhombus must have all four sides congruent. A quadrilateral has four sides. Use the Slope Formula to determine whether the opposite sides are parallel.

¬3

1) 3 ( O ¬ slope of N 13

¬2 All four sides have different slopes. Therefore, opposite sides are not parallel and the figure is a quadrilateral. 25. A trapezoid must have exactly one pair of opposite sides parallel. A parallelogram must have both pairs of opposite sides parallel. A square must have all four sides congruent and consecutive sides perpendicular. A rhombus must have all four sides congruent. A quadrilateral has four sides. Use the Slope Formula to determine whether the opposite sides are parallel. 03 slope of Q R ¬ 3 0 ¬1 3) 0 ( slope of S T ¬ 30 ¬1 3) 0 ( slope of Q T ¬ 3 0 ¬1 3 0 slope of R S ¬ 03 ¬1 Use the distance formula to compare the lengths of the sides. QR ¬ (3 0)2 (0 3 )2 ¬ 9 9 18 ST ¬ (3 0 )2 [0 ( 3)]2 ¬ 9 9 18 2 QT ¬ (3 0) [0 ( 3)]2 ¬ 9 9 18 RS ¬ (0 3 )2 (3 0)2 ¬ 9 9 18 All four sides have the same length and are congruent. Opposite sides are parallel. Because the slopes of consecutive sides are opposite reciprocals, consecutive sides are perpendicular. QRST is a square. 26. A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 4 1 slope of Q R ¬ 04

22 slope of G H ¬ 2 4

¬0 1 (1) slope of J K ¬ 6 (4) ¬0

2 (1) K ¬ slope of G 2 (4) ¬3 2

1) 2 ( slope of H J ¬ 46 ¬3 2 Exactly one pair of opposite sides is parallel, so GHJK is a trapezoid. 24. A trapezoid must have exactly one pair of opposite sides parallel. A parallelogram must have both pairs of opposite sides parallel. A square must have all four sides congruent and consecutive sides perpendicular. A rhombus must have all four sides congruent. A quadrilateral has four sides. Use the Slope Formula to determine whether the opposite sides are parallel. 13 slope of M N ¬ 3 1

¬3 4

3) 3 ( slope of P S ¬ 4 4 ¬3 4

34 slope of P Q ¬ 4 0 ¬1 4

3) 1 ( 4 slope of R S ¬ 4 4 0 or undefined Exactly one pair of opposite sides is parallel, Q R and P S . So, PQRS is a trapezoid. Use the Distance Formula to determine whether the legs are congruent.

¬1 2

1 (2) slope of O P ¬ 3 (2) ¬1 5

273

Chapter 8

PQ ¬ (4 0)2 (3 4 )2 ¬ 16 1 ¬ 17 RS ¬ (4 4 )2 [1 (3)] 2 ¬ 0 16 ¬4 Since PQ RS, PQRS is not an isosceles trapezoid. 27. Use the Midpoint Formula to find the coordinates of the midpoints of P Q and R S .

31. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures W V is given by of the bases. So, the length of WV 21(DG EF). Since D G and E F are vertical, their lengths are given by y1 y2. Find WV. WV ¬1 2 (DG EF) ¬1 2 [2 (2) 5 (3)]

¬6 So, WV 6. 32. Given: H J G K , HGK JKG Prove: GHJK is an isosceles trapezoid. H J

4 1 (3) 4 S R : 2 , 2 ¬(4, 1)

4 4 0 3 Q P : ¬(2, 3.5) 2 , 2

G Proof:

Q and R S The coordinates of the midpoints of P are A(2, 3.5) and B(4, 1), respectively.

K HJ

GK

HGK

Given

28. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. So, the length of A B is given by AB 1 2 (QR PS). To find the lengths of the bases, recognize that the bases are the hypotenuses of two special right triangles, 3-4-5 and 6-8-10. Find AB.

GHJK is a trapezoid.

HG

Def. of trapezoid

JK

CPCTC

GHJK is an isosceles trapezoid.

AB ¬1 2 (QR PS) ¬1 2 (5 10)

Def. of isosceles trapezoid

33. Given: TZX YXZ Prove: XYZW is a trapezoid. T W 1 Z

¬7.5 So, AB 7.5. 29. A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula.

2

X Proof:

25 slope of D E ¬ 2 5

Y TZX

YXZ

Given

¬3 7

1

3 (2) slope of F G ¬ 5 (2)

WZ || XY

2

CPCTC

¬1 7 The slopes of D G and E F are undefined. They are both vertical; therefore, they are parallel. Exactly one pair of opposite sides is parallel, D G and E F . So, DEFG is a trapezoid. Use the Distance Formula to determine whether the legs are congruent. DE ¬ (2 5)2 (2 5 )2 ¬ 49 9 ¬ 58 2 GF ¬ [5 (2)] [3 ( 2)]2 ¬ 49 1 ¬ 50 Since DE GF, DEFG is not an isosceles trapezoid. 30. Use the Midpoint Formula to find the coordinates of the midpoints of D E and G F .

If alt. int. are , then the lines are ||.

XYZW is a trapezoid. Def. of trapezoid

34. Given: ZYXP is an isosceles trapezoid. Prove: PWX is isosceles.

X

Y

W P

Proof:

Z ZYXP is an isosceles trapezoid. Given

Y

Z

WY

Base of an isos. trap. are .

WX WP

(3) 2 5 2 F G : ¬(1.5, 2.5) 2 2 , 5 2 5 2 E D : ¬(1.5, 3.5) 2 , 2

WZ

If 2 of a are , the sides opp. are .

XY WY, PZ WZ

WY

Segment Addition

WZ

Def. of

WX

XY

WP

PZ

Substitution

The coordinates of the midpoints of D E and G F are W(1.5, 3.5) and V(1.5, 2.5), respectively.

PWX is isosceles. Def. of isos.

Chapter 8

JKG

Given

274

XY

PZ

Def. of isos. trap.

XY

PZ

Def. of

WX

WP

Subtraction

WX Def. of

WP

35. Given: E and C are midpoints of A D and D B . D A D B Prove: ABCE is an isosceles trapezoid. D

39.

6

R

S

M

E

1 3 2

4

P

C X

A Proof:

Y

B V

E and C are midpoints of AD and DB. Given

AD

DB

Given

EC || AB

A

A segment joining the midpoints of two sides of a triangle is parallel to the third side.

2 is suppl. to A, 4 is suppl. to B. Consec.

T 3

are suppl.

B

Isos.

2

Th.

A Extend R V and S T to intersect at A. Since RSTV is an isoceles trapezoid, R S. So RSA is isosceles. Then R A SA . RA RX XA and SA SY YA. Since RA SA and RX SY, XA YA. By the Converse of the Triangle Proportionality Theorem, X Y R S . Since R S V T , Y X V T . Let M and P be the midpoints of R X and 1 Y S , respectively. Draw M P . RX 2(XV), so 2RX 1 XV. RM MX 2RX. So RM MX XV. Similarly, SP PY YT. By an argument similar to the one above, M P R S, P M X Y , M P V T . So X Y is the median of isosceles trapezoid MPTV. And M P is the median of isosceles trapezoid RSYX. 1 1 So, MP 2(RS XY) and XY 2(MP VT)

4 suppl. to are .

ABCE is an isos. trapezoid. Def. of isos. trapezoid

36. Given: ABCD is an isosceles trapezoid. C B A D B A C D Prove: A D ABC DCB A B F

1

C

E D

1

MP 2(6 XY) XY 2(MP 3) 1 MP 3 2XY Substitute this expression for MP into the second equation.

Proof: Draw auxiliary segments so that B F A D and C E A D . Since B C A D and parallel lines are everywhere equidistant, B F C E . Perpendicular lines form right angles, so BFA and CED are right angles. BFA and CED are right triangles by definition. Therefore, BFA CED by HL. A D by CPCTC. Since CBF and BCE are right angles and all right angles are congruent, CBF BCE. ABF DCE by CPCTC. So, ABC DCB by angle addition. 37. Sample answer: D C

1

1

XY 2[(3 2XY) 3] 1 1 XY 2(6 2XY) 1

XY 3 4XY 3 XY 3 4 XY 4 40. It is not possible. Since pairs of base angles of an isosceles trapezoid are congruent, if two angles are right, all four angles will be right. Then the quadrilateral would be a rectangle, not a trapezoid. 41. Sample answer: Trapezoids are used in monuments as well as other buildings. Answers should include the following. • Trapezoids have exactly one pair of opposite sides parallel. • Trapezoids can be used as window panes. 42. Quadrilateral WXYZ is a trapezoid because exactly one pair of opposite sides is parallel, W X and Y Z .

A B 38. Sample answer: 2 cm

275

Chapter 8

43. B; points in the shaded region have the following characteristics: x 0, y 0, and y 5 3 x 5. The only choice that satisfies all three requirements is B, (1, 3).

54. Solve the proportion for y. 20 5 ¬ y4 28

5(28) ¬20(y 4) 140 ¬20y 80 60 ¬20y 3 ¬y 55. Solve the proportion for y.

Page 445 Maintain Your Skills 44. Opposite angles of a rhombus are congruent, so QLM ¬QPM. Find x. QLM ¬QPM mQLM ¬mQPM 2x2 10 ¬8x 2x2 8x 10 ¬0 x2 4x 5 ¬0 (x 5)(x 1) ¬0 x 5 0 or x 1 0 x5 x 1 x must be greater than zero (otherwise mQPM is negative), so x 5. The diagonals of a rhombus bisect the angles, so mLPQ 1 2 mQPM, and mQPM 8(5) or 40. Therefore, mLPQ 20.

2y 52 ¬ 36 9

36(2y) ¬52(9) 72y ¬468 1 3 y ¬ 2 56. Find the slope of a segment given the endpoints (0, a) and (a, 2a). y y x2 x1 2a a ¬ a 0

2 1 slope of segment ¬

¬1 57. Find the slope of a segment given the endpoints (a, b) and (a, b). y2 y1 slope of segment ¬

45. By definition, a rhombus has four congruent sides, so Q L M P and QL 10. 46. Consecutive angles in a rhombus are supplementary, so QLM and LQP are supplementary. From Exercise 44, x 5. So mQLM 2(5)2 10 or 40. Find mLQP. mQLM mLQP ¬180 40 mLQP ¬180 mLQP ¬140 47. The diagonals of a rhombus bisect the angles, so 1 mLQM 1 2 mLQP. mLQM 2 (140) or 70.

x2 x1 b b ¬ a ( a)

¬0 58. Find the slope of a segment given the endpoints (c, c) and (c, d). y2 y1 slope of segment ¬ x2 x1 c d ¬ cc d c ¬ 0 , which is undefined

48. By definition, a rhombus has four congruent sides, so the perimeter is 4(10) or 40. 49. Use the Distance Formula to find RS and TV. RS ¬ (7 0)2 (3 4)2 ¬ 49 4 9 7 2 TV ¬ [3 ( 4)]2 [1 (7)]2 ¬ 49 6 4 113 50. Find the coordinates of the midpoints of R T and V S using the Midpoint Formula.

59. Find the slope of a segment given the endpoints (a, b) and (2a, b).

51. No; RSTV is not a rectangle because opposite sides are not congruent (Exercise 49) and the diagonals do not bisect each other (Exercise 50). 52. Solve the proportion for y.

61. Find the slope of a segment given the endpoints (b, c) and (b, c).

y y x2 x1 b) b ( ¬ 2a a b 2 ¬ a


60. Find the slope of a segment given the endpoints (3a, 2b) and (b, a). y y x2 x1 2b a ¬ b 3a a 2b ¬ 3a b


0 (4) 4 (7) 3 V S : 2, 2 2, 2 7 3 3 1 T R : (2, 1) 2 , 2

y y x2 x1 c c ¬ b b ¬bc


16 24 38 ¬ y

16y ¬24(38) 16y ¬912 y ¬57 53. Solve the proportion for y. y 17 ¬ 30 6

30y ¬17(6) 30y ¬102 17 y ¬ 5

Chapter 8

276

Opposite sides are parallel. Since one diagonal is vertical and the other is horizontal, they are perpendicular. Since the slopes of consecutive sides are not opposite reciprocals, they are not perpendicular. So, MNPQ is a rhombus. 4. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find MN.

Page 445 Practice Quiz 2 1. BAD is a right angle, so BAC and CAD are complementary. Find x. mBAC mCAD ¬90 (2x 1) (5x 5) ¬90 7x ¬84 x ¬12 2. ABD BDC because they are alternate interior angles. Find y. ABD ¬BDC mABD ¬mBDC y2 ¬3y 10 y2 3y 10 ¬0 (y 5)(y 2) ¬0 y 5 0 or y 2 0 y5 y 2 If y 5, mABD 52 or 25. If y 2, mABD (2)2 or 4. ABD BAC because they are base angles of an isosceles triangle, so their measures are equal. From Question 1, x 12. So, mBAC 2(12) 1 or 25, therefore, y is 5. Reject y 2 because it leads to a contradiction. 3. y N

MN ¬1 2 (TR VS) ¬1 2 (44 21) ¬32.5 5. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find VS. MN ¬1 2 (TR VS) 25 ¬1 2 (32 VS)

50 ¬32 VS 18 ¬VS

Page 446 Reading Mathematics: Hierarchy of Polygons 1. False; all jums are mogs and some mogs are jums. Mogs is of a higher class than jums in the hierarchy. 2. False; both jebs and jums are mogs, but no jebs are jums. Jebs and jums are distinct members of the same class. 3. True; all lems are jums because every element of a class is contained within any class linked above it in a hierarchy diagram. 4. True; some wibs are jums and some wibs are jebs. Jums and jebs are members of the same class in the hierarchy. Wibs is a member of the class below and is directly linked to both jums and jebs. 5. True; all mogs are bips because every element of a class is contained within any class linked above it in a hierarchy diagram. 6. All triangles are polygons. Both isosceles and scalene triangles are triangles. All equilateral triangles are isosceles triangles.

4

x 12 8

4

M

4 4

Q

8

P

12

If opposite sides are parallel, then MNPQ can be a rhombus, a rectangle, or a square. If diagonals are perpendicular, then MNPQ can be a rhombus or a square. If consecutive sides are perpendicular, then MNPQ is a rectangle or a square. Use the Slope Formula to determine whether opposite sides are parallel and consecutive sides are perpendicular. 3 3 slope of M N ¬ 5 (2)

¬2

Polygons

9 (3) Q ¬ slope of P 2 1

Triangles

¬2

3) 3 ( Q ¬ slope of N 2 1

Isosceles

Scalene

¬2

3 (9) P ¬ slope of M 5 (2)

Equilateral

¬2 Use the Slope Formula to determine whether the diagonals are perpendicular.

8-7

3 ( 9) slope of N P ¬ 2 (2) 1 2 ¬ 0 , which is undefined 3 (3) Q ¬ slope of M 5 1

Coordinate Proof With Quadrilaterals

Page 448 Geometry Software Investigation: Quadrilaterals 1. See students’ work. 2. A parallelogram is formed by the midpoints since the opposite sides are congruent.

¬0

277

Chapter 8

8. Given: D(195, 180), E(765, 180), F(533, 0), G(195, 0) Prove: DEFG is a trapezoid.

Pages 449–450 Check for Understanding 1. Place one vertex at the origin and position the figure so another vertex lies on the positive x-axis. 2. Sample answer:

y

D (195, 180)

y

D

E(765, 180)

C

x

O A

3.

G(195, 0)

O

B

0 0 F Slope of G 533 195 or 0

C (a, a b)

O A(0, 0)

x

Proof: 180 180 Slope of D E 765 195 or 0

y

D (0, a b)

F(533, 0)

180 0 4 5 F Slope of E 765 533 or 58 180 0 Slope of D G 195 195 or undefined E D and G F have the same slope, so exactly one pair of opposite sides are parallel. Therefore, DEFG is a trapezoid.

B(a, 0) x

4. The quadrilateral is a square. Opposite sides of a square are congruent and parallel, and its interior angles are all 90°. So, the x-coordinate of C is a and the y-coordinate is a. The coordinates of C are (a, a). 5. The quadrilateral is a parallelogram. Opposite sides of a parallelogram are congruent and parallel. So, the y-coordinate of D is b. The length of A B is a, and the length of D C is a. So, the x-coordinate of D is (a c) a or c. The coordinates of D are (c, b). 6. Given: ABCD is a parallelogram. Prove: A C and D B bisect each other.

Pages 450–451 9.

y

D (b, c)

O A(0, 0)

10.

Practice and Apply C (a b, c)

B(a 2b, 0) x

y

D (a, b)

C (c a, b)

y

D (b, c)

C (a b, c) 11.

O A(0, 0)

B(a, 0) x

Proof: 0 (a b) c The midpoint of A C ¬ , 0 2 2

a b c ¬ 2 , 2 a b 0c The midpoint of D B 2 , 2 a b c ¬ 2 , 2

12.

C A and D B bisect each other. 7. Given: ABCD is a square. Prove: A C D B y

D (0, a)

O A(0, 0)

13.

C (a, a)

B(a, 0) x

Proof: 0 a Slope of D B a 0 or 1

14.

0 a C Slope of A 0 a or 1 C is the negative reciprocal of the The slope of A slope of D B , so they are perpendicular.

Chapter 8

B(c, 0) x The quadrilateral is a parallelogram. Opposite sides of a parallelogram are congruent and parallel. So, the y-coordinate of B is c. G is a b , and the length of B C The length of H is a b. So, the x-coordinate of B is a (a b) or b. The coordinates of B are (b, c). The quadrilateral is a square. Opposite sides of a square are congruent and parallel, and its interior angles are all 90°. So, the x-coordinate of A is b and the y-coordinate is b, and the x-coordinate of E is b and the y-coordinate is b. The coordinates of A and E are (b, b) and (b, b), respectively. The quadrilateral is a parallelogram. Opposite sides of a parallelogram are congruent and parallel. So, the y-coordinates of E and G are c and 0, respectively. The length of H G is a, and the length of E F is a. So, the x-coordinate of G is a, and the x-coordinate of E is (a b) a or b. The coordinates of G and E are (a, 0) and (b, c), respectively. The quadrilateral is an isosceles trapezoid. The top and bottom sides of the trapezoid are parallel, so the y-coordinate of M is c. The length of L M is a 2b, so the x-coordinate of M is (a b) (a 2b) or b. The coordinates of M are (b, c). O A(0, 0)

278

19. Given: isosceles trapezoid ABCD with A D B C Prove: B D A C

15. The quadrilateral is a rectangle. Opposite sides of a rectangle are congruent and parallel, and its interior angles are all 90°. So, the y-coordinates of T and W are c and c, respectively. The origin is at the center of the rectangle, so the x-coordinates of T and W are both 2a (the opposites of the x-coordinates of U and V). The coordinates of T and W are (2a, c) and (2a, c), respectively. 16. The quadrilateral is an isosceles trapezoid. The right and left sides of the trapezoid are parallel, so the x-coordinates of T and S are 0 and a, respectively. The length of Q T is a, so the y-coordinate of T is a. The length of R 1 S is 2a 2c, so the 2 y-coordinate of S is (a c) (2a 2c) or a c.

y

D (b, c) C (a b, c)

Proof: BD ¬ (a b )2 (0 c)2 (a b )2 c2 AC ¬ ((a b) 0 )2 (c 0)2 (a b )2 c2 BD ¬AC and B D A C 20. Given: ABCD is a trapezoid with median X Y . Prove: X Y A B and X Y D C y

A( b, c)

The coordinates of T and S are 0, 1 2 a and (a, a c), respectively.

b c 2a b c C is Y are 2 , 2 . The midpoint of B 2, 2 . B 0, the slope of X Y 0 and the The slope of A slope of D C 0. Thus, X Y A B and X Y D C . 21. Given: ABCD is a rectangle. Q, R, S, and T are midpoints of their respective sides. Prove: QRST is a rhombus.

B(a, b)

C (a, 0) x

y

D(0, b)

R

C(a, b)

Q O A(0, 0)

y

O A(0, 0)

C (a, 0) x

Proof: The midpoint of A D is X. The coordinates

Proof: Use the Distance Formula to find 2 b2 AC a and BD a2 b2. A C and D B have the same length, so they are congruent. 18. Given: ABCD and A C B D Prove: ABCD is a rectangle. D (b, c)

Y O D(0, 0)

y

O D(0, 0)

B(a b, c)

X

17. Given: ABCD is a rectangle. Prove: A C D B A(0, b)

B(a, 0) x

O A(0, 0)

C (a b, c)

S B(a, 0) x

T

Proof: 0 b0 0 b Midpoint Q is 2 , 2 or 0, 2 .

0 bb a a 2b a Midpoint R is 2 , 2 or 2, 2 or 2, b a a b0 2a b b Midpoint S is 2 , 2 or 2, 2 or a, 2. 0 00 a a Midpoint T is 2 , 2 or 2, 0. ¬ a b QR b a2 0 b 2 2 2

RS a a2 b2 b a a ¬ b2 or b2 2 2 b a ST a a2 b2 2 0 ¬ 2 a QT b 0 2 0 2 a ¬ a2 b2 or b2 2

B(a, 0) x

Proof: AC (a b 0)2 (c 0)2 2 2 BD (b a ) (c 0) But AC BD and 2 (c (a b 0)2 (c 0)2 ¬ (b a) 0)2. 2 2 2 (a b 0) (c 0) ¬(b a) (c 0)2 (a b)2 c2 ¬(b a)2 c2 2 a 2ab b2 c2 ¬b2 2ab a2 c2 2ab ¬2ab 4ab ¬0 a 0 or b ¬0 Because A and B are different points, a 0. Then b 0. The slope of A D is undefined and the slope of A B 0. Thus A D A B . DAB is a right angle and ABCD is a rectangle.

2

2

2

2

2

2

2

2

2

2

2

2

2

2

2

2

2

2

2

2

QR RS ST QT Q R R S S T Q T QRST is a rhombus.

279

Chapter 8

22. Given: RSTV is a quadrilateral. A, B, C, and D are midpoints of sides R S , T S , T V , and V R , respectively. Prove: ABCD is a parallelogram. y

T (2d, 2b)

S(2a, 2e) B O R(0, 0)

24.

V(2c, 0) x

Proof: Place quadrilateral RSTV on the coordinate plane and label coordinates as shown. (Using coordinates that are multiples of 2 will make the computation easier.) By the Midpoint Formula, the coordinates of A, B, C, and D are

2a 2b 2d B , 2e ¬(d a, e b); 2 2 2c 2d ¬(d c, b); and C , 22b 2 c 0 D22 , 2 ¬(c, 0). 2a e 2 A 2 , 2 ¬(a, e);

Find the slopes of A B and D C . Slope of A B Slope of D C y y

y y

2 1 m ¬ x x

2 1 m x x

1

2

(e b) e

1

0 b c (d c)

¬ (d a) a

b b b ¬d d or d The slopes of A B and D C are the same so the segments are parallel. Use the Distance Formula to find AB and DC. 2 (( AB ¬ ((d a) a) e b) e)2 2 2 ¬ d b DC ¬ ((d c) c )2 (b 0)2 2 b2 ¬ d Thus, AB DC. Therefore, ABCD is a parallelogram because if one pair of opposite sides of a quadrilateral are both parallel and congruent, then the quadrilateral is a parallelogram. 23. Sample answer:

Page 451

c

C (a c, b)

M

a

X

c

Y

a D (2a c, 0)

Graph points A(0, 0) and B(a, b). If ABCD is an isosceles trapezoid, B C A D . So B C is horizontal. Let b be the y-coordinate of C. Since ABCD is isosceles AB CD. AX a. Let XY c. Then YD a because ABX DCY by HL. The coordinates of C and D are C(a c, b) and D(2a c, 0).

Chapter 8

N

Proof: Statements Reasons 1. MNOP is a trapezoid with 1. Given bases M N and O P . N M Q O

x

A (0, 0)


30. Given: MNOP is a trapezoid with bases M N and P O , M N Q O Prove: MNOQ is a parallelogram. P Q O

y

B (a, b)

x

B(a, 0)

25. No, there is not enough information given to prove that the sides of the tower are parallel. 26. From the information given, we can approximate the height from the ground to the top level of the tower. 27. Sample answer: The coordinate plane is used in coordinate proofs. The Distance Formula, Midpoint Formula and Slope Formula are used to prove theorems. Answers should include the following. • Place the figure so one of the vertices is at the origin. Place at least one side of the figure on the positive x-axis. Keep the figure in the first quadrant if possible and use coordinates that will simplify calculations. • Sample answer: Theorem 8.3: Opposite sides of a parallelogram are congruent. 28. D; ABCD is a parallelogram, so opposite sides are parallel. B C A D and B C lies along the x-axis, so A D is parallel to the x-axis and is horizontal. Therefore, D must have the same y-coordinate as A. Opposite sides of a parallelogram are congruent, so A D B C and AD BC. According to the Distance Formula, BC (x x1)2 (y2 y1)2 2 2 (c b ) 0 c b. So, the length of AD is c b. A D is horizontal, the x-coordinate of D must be greater than that of A, and c b 0, therefore, the x-coordinate of D must be c b. The coordinates of point D are (c b, a). 29. A; if p 5, then 5 p2 p 5 (5)2 (5) or 15.

A

2

D(c, d) C(a 4.5, b)

O

A(0, 0)

C

D

y

2. Def. of trapezoid 2. O P M N 3. MNOQ is a parallelogram. 3. If one pair of opp. sides are and , the quad. is .

280

31. Opposite angles of a rhombus are congruent and the diagonals of a rhombus bisect opposite angles, so RMP MPR and their measures are equal. Since RMP JMK and mJMK 55, mMPR 55. 32. KJM and MLK are right angles and JKM and KLM are right triangles because the interior angles of a rectangle are right angles. Opposite sides of a rectangle are parallel, so LKM JMK and their measures are equal because they are alternate interior angles. Therefore, mLKM 55. The sum of the measures of the interior angles of a triangle is 180. Find mKML. mKLM mLKM mKML ¬180 90 55 mKML ¬180 mKML ¬35 33. KLM is a right angle because the interior angles of a rectangle are right angles. Opposite angles of a rhombus are congruent, so MLP MRP and their measures are equal. Therefore, mMLP 70. The measure of KLP is the sum of the measures of KLM and MLP. Find mKLP. mKLP ¬mKLM mMLP mKLP ¬90 70 mKLP ¬160 34. Let x represent the geometric mean. x 7 x ¬ 1 4 x2 ¬98 x ¬ 98 x ¬9.9 The geometric mean of 7 and 14 is 98 or about 9.9. 35. Let x represent the geometric mean. 2 ¬x 5 x

36. 37.

38.

39.

Chapter 8 Study Guide and Review Page 452 Vocabulary and Concept Check 1. 2. 3. 4. 5. 6. 7. 8.

true true false; rectangle true false; trapezoid false; rhombus true true

Pages 452–456 Lesson-by-Lesson Review 9. Use the Interior Angle Sum Theorem. S 180(n 2) 180(6 2) 720 The measure of an interior angle of a hexagon is 72 0 6 or 120. 10. Use the Interior Angle Sum Theorem. S 180(n 2) 180(15 2) 2340 The measure of an interior angle of a regular 234 0 15-gon is 15 or 156. 11. Use the Interior Angle Sum Theorem. S 180(n 2) 180(4 2) 360 The measure of an interior angle of a square is 36 0 4 or 90. 12. Use the Interior Angle Sum Theorem. S 180(n 2) 180(20 2) 3240 The measure of an interior angle of a regular 324 0 20-gon is 20 or 162. 13. Since n 4, the sum of the measures of the interior angles is 180(4 2) or 360. Write an equation to express the sum of the measures of the interior angles of the polygon. 360 mW mX mY mZ

6 5

x2 ¬60 x ¬ 60 x ¬7.7 The geometric mean of 2 5 and 6 5 is 60 or about 7.7. VXY is an exterior angle of WVX. So mWVX mVXY. VZ and XZ are equal, so V Z X Z and VXZ is an isosceles triangle. The base angles of an isosceles triangle are congruent, so XVZ VXZ and mXVZ mVXZ. WYV XYV because they are the same angle. VXY and XYV are two interior angles of VXY. The side of VXY opposite VXY measures 6 6 or 12. The side of VXY opposite XYV measures 8. According to Theorem 5.9, if one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. Therefore, mXYV mVXY. Z X X Z and V Z Y Z . XY VX, so mXZY mXZV by the SSS Inequality Theorem.

1 360 2a 8 a (a 28) (a 2) 7 360 2a 18 378 7 2a

108 a

Use the value of a to find the measure of each angle. mW 1 2 (108) 8 or 62, mX 108, mY

108 28 or 80, and mZ 108 2 or 110.

281

Chapter 8

14. Since n 5, the sum of the measures of the interior angles is 180(5 2) or 540. Write an equation to express the sum of the measures of the interior angles of the polygon. 540 mA mB mC mD mE 540 (x 27) (1.5x 3) (x 25) (2x 22) x 540 6.5x 33 507 6.5x 78 x Use the value of x to find the measure of each angle. mA 78 27 or 105, mB 1.5 78 3 or 120, mC 78 25 or 103, mD 2 78 22 or 134, and mE 78. 15. BCD BAD because opposite angles in a parallelogram are congruent. Find mBAD. mBAD mCAD mBAC 20 32 52 So, mBCD 52. 16. The diagonals of a parallelogram bisect each other, so AF and CF are equal. Therefore, AF 7. 17. Consecutive angles in a parallelogram are supplementary. So, mADC 180 mBCD. From Exercise 15, mBCD 52. So, mADC 180 52 or 128. ADB CBD because they are alternate interior angles. So mADB 43. mBDC mADC mADB 128 43 85 So, mBDC 85. 18. Opposite sides of a parallelogram are congruent, so their measures are equal and BC AD. Therefore, BC 9. 19. Opposite sides of a parallelogram are congruent, so their measures are equal and CD AB. Therefore, CD 6. 20. Consecutive angles in a parallelogram are supplementary. So, mADC 180 mBAD. Find mBAD. mBAD mCAD mBAC 20 32 52 So, mADC 180 52 or 128. 21. No;

AD ¬ [2 (1)]2 [5 (2)] 2 ¬ 50 BC ¬ (4 6 )2 [4 (3)] 2 ¬ 53 AD BC, so ABCD is not a parallelogram. 22. Yes; y 12

J

K

4

L

H 4

x 12

8

If the midpoints of the diagonals are the same, the diagonals bisect each other. If the diagonals of a quadrilateral bisect each other, then the quadrilateral is a parallelogram. Find the midpoints of H K and J L .

4 4 9 6 5 L J : 2 , 2 ¬ 2 , 5 5 46 0 5 K H : 2 , 2 ¬ 2, 5

The midpoints of H K and J L are the same, so HKJL is a parallelogram. 23. Yes; y

V

12 8

W

4

T x

12

8

4 S

4

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram. 1 5 slope of S T ¬ 2 2 ¬3 2

13 7 slope of V W ¬ 10 (14) ¬3 2

5 13 slope of T V ¬ 2 ( 10) ¬2 3

y

A

8

1 7 slope of S W ¬ 2 (14)

B

¬2 3

Since opposite sides have the same slope, S T V W and T V S W . Therefore, STVW is a parallelogram by definition.

x

D C If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent. Chapter 8

282

24. The diagonals of a rectangle bisect each other and are congruent, so AF 1 2 AC. AF ¬1 2 AC 2x 7 ¬1 2 (26)

2x ¬13 7 x ¬3 So, AF 2(3) 7 or 13. 25. The diagonals of a rectangle are congruent and bisect each other. So, the triangles formed by the diagonals of a rectangle are isosceles. Therefore, 2 1 and m2 52. 26. The diagonals of a rectangle bisect each other and are congruent, so C F D F . Find x.

30.

CF ¬D F CF ¬DF 4x 1 ¬x 13 3x ¬12 x ¬4 27. The interior angles of rectangles are right angles, and the sum of the measures of the interior angles of a triangle is 180. So, the sum of the measures of 2 and 5 is 90. Find m5. m2 m5 ¬90 (70 4x) (18x 8) ¬90 14x ¬28 x ¬2 So, m5 18(2) 8 or 28. 28. Find the slopes of R S , S T , T V , and V R .

31. 32.

33.

5 (5) S ¬ slope of R 3 0

¬0

5 4 T ¬ slope of S 0 (3)

¬3

4 4 V ¬ slope of T 30 ¬0

34.

4 ( 5) R ¬ slope of V 0 (3)

So, R S T V and S TV R . Use the Distance Formula to determine whether the diagonals of quadrilateral RSTV are congruent. RT ¬ (0 4 )2 (0 7)2 ¬ 16 4 9 ¬ 65 2 SV ¬ [6 (2)] (3 4)2 ¬ 64 1 ¬ 65 Since the opposite sides are parallel and the diagonals are congruent, RSTV is a rectangle. The diagonals of a rhombus bisect the angles, so 1 2. Find x. 1 ¬2 m1 ¬m2 2x 20 ¬5x 4 24 ¬3x 8 ¬x The diagonals of a rhombus bisect each other, so 1 AF 1 2 AC 2 (15) or 7.5. The diagonals of a rhombus are perpendicular, so m3 is 90. Find y. m3 ¬90 y2 26 ¬90 y2 ¬64 y ¬8 or 8 C B A D , so ADY and BCY are supplementary. Find mBCY. mBCY mADY ¬180 mBCY 78 ¬180 mBCY ¬102 Both pairs of base angles of an isosceles trapezoid are congruent, so XBC BCY and mXBC 102. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find JM. AB ¬1 2 (KL JM)

¬3 The slopes of consecutive sides are not negative reciprocals, so consecutive sides are not perpendicular. Therefore, RSTV is not a rectangle. (Note: S T V R so RSTV is not even a parallelogram. So it is not a rectangle.) 29. If the opposite sides of a quadrilateral are parallel and the diagonals of the quadrilateral are congruent, then the quadrilateral is a rectangle. Find the slopes of R S , S T , T V , and V R .

57 ¬1 2 (21 JM)

114 ¬21 JM 93 ¬JM 35. Given: ABCD is a square. Prove: A C B D y

D(0, a)

0 3 S ¬ slope of R 06

C(a, a)

O A(0, 0) B(a, 0)

¬1 2

x

Proof: a 0 Slope of A C a 0 or 1

7 4 slope of T V ¬ 4 ( 2)

a 0 D Slope of B 0 a or 1

¬1 2

3 7 slope of S T ¬ 64

C is the negative reciprocal of the The slope of A slope of B D . Therefore, A C B D .

¬2

40 R ¬ slope of V 2 0

¬2

283

Chapter 8

36. Given: ABCD is a parallelogram. Prove: ABC CDA

If the midpoints of the diagonals are the same, the diagonals bisect each other. If the diagonals of a quadrilateral bisect each other, then the quadrilateral is a parallelogram. Find the midpoints of A C and B D .

y

D(b, c)

C (a b, c)

O A(0, 0) B(a, 0) Proof: AB (a 0 )2 (0 0)2 a2 02 or a

2 6 0 (5) 4, 5 D B : 2 , 2 2 4 4 3 (8) 4, 5 C A : 2 , 2 2

x

2 (c [(a b) b] c)2 a2 02 or a DC

The midpoints of A C and B D are the same, so the diagonals bisect each other and ABCD is a parallelogram. 9. Yes;

(b 0 )2 (c 0)2 b2 c2 AD BC

[(a b) a ]2 (c 0)2

b2 c2

AB and DC have the same measure, so A B D C . AD and BC have the same measure, so A D B C . C A A C by the Reflexive Property. Therefore, ABC CDA by SSS. 37. The quadrilateral is an isosceles trapezoid. The top and bottom sides of the trapezoid are parallel, so the y-coordinate of P is c. The length of M N is 4a, so the x-coordinate of P is 4a a or 3a. The coordinates of P are (3a, c). 38. The quadrilateral is a parallelogram. Opposite sides of a parallelogram are congruent and parallel. So, the y-coordinate of U is c. The length of V W is b (a) or a b. So the length of T U is also a b. So, the x-coordinate of U is (a b) 0 or a b. The coordinates of U are (a b, c).

y

12

T

8

V

S 4

W 8

x

O

4 4

8

4

First use the Distance Formula to determine whether the opposite sides are congruent. ST ¬ (2 2)2 (6 1 1)2 ¬ 41 VW ¬ [3 ( 1)]2 (8 3)2 ¬ 41 Since ST VW, S T V W . Next, use the Slope Formula to determine whether S T V W .


6 11 T ¬ slope of S 2 2

Page 457

¬5 4

1. true 2. false;

8 3 slope of V W ¬ 3 ( 1)

3. false;

¬5 4

ST and V W have the same slope, so they are parallel. Since one pair of opposite sides is congruent and parallel STVW is a parallelogram. 10. No;

4. HK F G because opposite sides of parallelograms are congruent. 5. FKJ HGJ because alternate interior angles are congruent. 6. FKH FGH because opposite angles of parallelograms are congruent. 7. G H F K because opposite sides of parallelograms are parallel. 8. Yes;

x 4

4 8

Chapter 8

D

4

8

G

8

12

F

8

If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent.

x

B

J O

A O

H

4

y 4

y

8

12

C

284

FG ¬ (7 4 )2 [ 3 (2)] 2 ¬ 10 HJ ¬ (6 1 2)2 (4 2 )2 ¬ 40 2 ( GH ¬ (4 6) 2 4)2 ¬ 40 FJ ¬ (7 1 2)2 (3 2)2 ¬ 50 Since the measures of both pairs of opposite sides are not equal, they are not congruent. Therefore, FGHJ is not a parallelogram. 11. Yes; y

14. 8

D

4

C O

A 4

8

12

x

4 8

B

If the four sides are congruent, then parallelogram ABCD is either a rhombus or a square. If consecutive sides are perpendicular, then ABCD is a rectangle or a square. Use the Distance Formula to compare the lengths of the sides. AB ¬ (12 6)2 [0 (6)] 2 ¬ 36 3 6 ¬6 2 2 ( BC ¬ (6 0) 6 0)2 ¬ 36 3 6 ¬6 2 2 (0 CD ¬ (0 6) 6)2 ¬ 36 3 6 ¬6 2 AD ¬ (12 6)2 (0 6 )2 ¬ 36 3 6 ¬6 2 Use the Slope Formula to determine whether the consecutive sides are perpendicular.

Y

X

Z W

y

x O

If both pairs of opposite sides of a quadrilateral are congruent, then the quadrilateral is a parallelogram. Use the Distance Formula to determine whether the opposite sides are congruent. 2 (2 WX ¬ [4 (3)] 6)2 ¬ 17 YZ ¬ (2 1 )2 (7 3)2 ¬ 17 XY ¬ (3 2)2 (6 7 )2 ¬ 26 WZ ¬ (4 1)2 (2 3 )2 ¬ 26 Since the measures of both pairs of opposite sides are equal, they are congruent. Therefore, WXYZ is a parallelogram. 12. The diagonals of a rectangle bisect each other, so P Q P S . Find x. P Q ¬P S QP ¬PS 3x 11 ¬4x 8 3 ¬x Find QS. QS QP PS (3x 11) (4x 8) 7x 19 7(3) 19 40 So, QS 40. 13. Opposite sides of a rectangle are parallel, so QTR SRT because they are alternate interior angles. Find x2. QTR ¬SRT mQTR ¬mSRT 2x2 7 x2 ¬18 x2 ¬25 So, mQTR 2(25) 7 or 43.

6) 0 ( B ¬ slope of A 12 6

¬1 0 6 C ¬ slope of B 60 ¬1 0 6 D ¬ slope of C 06

¬1 06

D ¬ slope of A 12 6

¬1 B and C D are negative Since the slopes of A reciprocals of the slopes of B C and A D , consecutive sides are perpendicular. The lengths of the four sides are the same, so the sides are congruent. Therefore, ABCD is a rectangle, a rhombus, and a square.

285

Chapter 8

15. 12 8

17.

y

y

D(?, ?)

B

A

C(?, ?)

C D O

4

8

12

A(0, 0)

x

If the four sides are congruent, then parallelogram ABCD is a square or a rhombus. If the diagonals are congruent, then ABCD is a square or a rectangle. If the diagonals are perpendicular, then ABCD is a square or a rhombus. Use the Distance Formula to compare the lengths of the sides. AB ¬ (2 5)2 (4 6 )2 ¬ 49 4 53 BC ¬ (5 1 2)2 (6 4 )2 ¬ 49 4 53 CD ¬ (12 5)2 (4 2)2 ¬ 49 4 53 AD ¬ (2 5)2 (4 2 )2 ¬ 49 4 53 Use the Distance Formula to compare the lengths of the diagonals. AC ¬ (2 12)2 (4 4 )2 ¬ 196 0 14 BD ¬ (5 5 )2 (6 2)2 ¬ 0 16 4 Use the Slope Formula to determine whether the diagonals are perpendicular.

a

Y

b B(a 2b, 0)

Sample answer: To find the y-coordinates of C and D notice that C D is parallel to the x-axis. So C D is a horizontal segment, and C and D both have the same y-coordinate. Call it c. To find the x-coordinate of D, notice that AX b so the x-coordinate of D is b. The x-coordinate of c is the same as the x-coordinate of Y or a b. So the coordinates of D and C are D(b, c) and C(a b, c) 18. Given: trapezoid WXYZ with median S T Prove: W X S T Y Z y

W(0, 2d) S( a, d) Z( 2a, 0) O

X(b, 2d) T(a b, d) Y(2a b, 0) x

Proof: To prove lines parallel, show their slopes equal. 2d 2d The slope of WX is b 0 or 0. d d The slope of ST is (a b) (a) or 0.

00 The slope of YZ is (2a b) (2a) or 0. Since WX, ST, and YZ all have zero slope, they are parallel. 19. The median of a trapezoid is parallel to the bases, and its measure is one-half the sum of the measures of the bases. Find the length of the midchord of the keel. length of mid-chord 1 2 (length of root chord length of tip chord)

4 4 slope of A C ¬ 2 12

¬0 6 2 D ¬ slope of B 55 ¬4 0 , which is undefined C A is horizontal and B D is vertical, so the diagonals are perpendicular, but not congruent since AC BD. The lengths of the four sides are the same, so the sides are congruent. Therefore, ABCD is a rhombus. 16. The quadrilateral is a parallelogram. Opposite sides of a parallelogram are congruent and parallel. So, the y-coordinate of P is c. The length of M Q is b (a) or a b and the length of N P is a b. So, the x-coordinate of P is (a b) 0 or a b. The coordinates of P are (a b, c).

Chapter 8

x

b X

4

¬1 2 (9.8 7.4) ¬1 2 (17.2)

¬8.6 The length of the mid-chord is 8.6 ft. 20. C; use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S ¬180(n 2) (108)n ¬180(n 2) 108n ¬180n 360 0 ¬72n 360 360 ¬72n 5 ¬n The polygon has 5 sides.

286

8. Set y equal to zero to find the x-coordinate at which the graph crosses the x-axis. y ¬4x 5 0 ¬4x 5 4x ¬5 x ¬5 4 The point at which the graph crosses the x-axis is

Chapter 8 Standardized Test Practice Pages 458–459 1. C; the length of the ramp is the hypotenuse of a right triangle with legs measuring 3 meters and 5 meters. Use the Pythagorean Theorem to find the length of the hypotenuse. 2 b2 c ¬ a 2 ¬ 3 52 ¬ 34 ¬6 To the nearest meter, the length of the ramp should be 6 m. 2. D; the contrapositive of the statement “If an astronaut is in orbit, then he or she is weightless” is “If an astronaut is not weightless, then he or she is not in orbit.” 3. B; for the two rectangles to be similar, the measures of their corresponding sides must proportional. The ratio of the length to the width

54, 0. 9. If one side of a triangle is longer than another side, then the angle opposite the longer side has a greater measure than the angle opposite the shorter side. The side representing the path from Candace’s house to the theater is opposite a 55° angle, and the side representing the path from Julio’s house to the theater is opposite a 40° angle. Since 55 40, Julio’s house is closer to the theater. 10. C D is the altitude of right triangle ABC so, by Theorem 7.2, its measure is the geometric mean between the segments of the hypotenuse. Let x CD

of QRST is 7 4 or 7 : 4. The ratios of the choices, 28 21 14 7 7 7 from A to D, are: 14 2, 12 4 , 4 2 , and 8 .

x 4 x ¬ 2 5

11. The sides of a rhombus are congruent, so A C separates rhombus ABCD into two isosceles triangles. The base angles of an isosceles triangle are congruent, so ACD CAD. CDE is an exterior angle of ACD so mCDE mCAD mACD. Substituting mACD for mCAD, 116 mACD mACD 116 2(mACD) 58 mACD 12a. MNR and PQR are both right angles and all right angles are congruent, so MNR PQR. Since congruence of angles is reflexive, R R. MNR is similar to PQR because two angles are congruent (AA Similarity). 12b. The ratios of corresponding sides of similar

The dimensions, 21 cm by 12 cm, could be the dimensions of a rectangle similar to QRST. 4. C; the ladder, wall, and ground form a 30°-60°-90° right triangle. The ladder is the hypotenuse, the wall is the longer leg, and the ground is the shorter leg. In a 30°-60°-90° triangle, the length of the hypotenuse is twice the length of the shorter leg, and the length of the longer leg is 3 times the length of the shorter leg. So, the shorter leg is 24 3 ft. The 2 or 12 ft, and the longer leg is 12 ladder reaches 12 3 ft up the side of the house. 5. B; the diagonals of a rectangle are congruent, so L J K M . Find x. L J ¬K M JL ¬KM 2x 5 ¬4x 11 16 ¬2x 8 ¬x 6. C; the diagonals of a rhombus bisect each other but are not necessarily congruent. 7. A; the bases of a trapezoid are parallel, so A B is parallel to C D .

MR PR polygons are the same, so M N Q P.

400 a 40 0 The proportion is 126 120 . Solve for a. 400 a 40 0 126 ¬ 120

40 0 400 a ¬126 120

a ¬420 400 a ¬20 The distance across the sand trap, a, is 20 yards.

287

Chapter 8

c0 c 13b. The slope of A C is a b 0 or a b. c 0 c D is The slope of B b a or b a.

13a. Given: quadrilateral ABCD Prove: ABCD is a parallelogram y

D (b, c)

c c The product of the slopes is a b ba c2 2 2 2 b2 a2 . Since c a b , the product of the

C (a b, c)

b a slopes is b2 a2 or 1, so the diagonals of ABCD are perpendicular. 13c. Since the diagonals are perpendicular, ABCD is a rhombus. 2

O A(0, 0)

B(a, 0) x

Proof: c 0 c The slope of A D is C is b 0 or b . The slope of B c c 0 or . A and B C have the same slope aba b D so they are parallel. 2 (c 2 c2 AD (b 0) 0)2 b . 2 2 2 c2 BC (a b a) (c 0) b . Since one pair of opposite sides are parallel and congruent, ABCD is a parallelogram.

Chapter 8

288

2

Chapter 9 Transformations Page 461

9. sin A ¬2 3 A ¬sin1 2 3 A ¬41.8° The measure of angle 10. sin A ¬4 5 A ¬sin14 5 A ¬53.1° The measure of angle 9 11. cos A ¬ 1 2 9 A ¬cos1 12 A ¬41.4° The measure of angle 15 12. cos A ¬ 17 15 A ¬cos1 17 A ¬28.1° The measure of angle 4 0 1 5 13. 1 1 5 1

Getting Started

1.

y

B( 1, 3)

A(1, 3) x

O

2.

y

C( 3, 2) x

O

D( 3, 2) 3.

y

E( 2, 1) x

O

F( 1, 2)

A is approximately 41.8.




0(4) 1(1) 1(5) 0(5) 1(5) (1)(5) 1(4) (1)(1) 5 1 10 5 1 0 0 2 14. 1 1 2 3 1(0) 0(2) 1(2) 0(3) 1(0) 1(2) 1(2) 1(3) 0 2 2 1 0 1 4 5 3 15. 1 0 2 5 1 0(5)1(1) 0(3)1(2) 0(4)1(5) 1(3)0(2) 1(4)0(5) 1(5)0(1) 2 5 1 3 4 5

4.

y

G(2, 5)

x

O

H(5, 2) 5.

y

J( 7, 10) 8

K( 6, 7)

4 12

8

O

4

x

16.

6.

y

10 10 13 ¬

x

O

31

L(3, 2) M(6, 4) 7. tan A ¬3 4

3 3 2 1 2 1

1( 3) 0( 1) 1( 3) 0( 2) 1( 1) 0(3) 0( 1) ( 1)(3) 0( 3) ( 1)( 1) 0( 3) ( 1)( 2)

1(2) 0(1) 0(2) ( 1)(1)

3 3 2 1 2 1

Page 462 Geometry Activity: Transformations 1. Rotation; the figure has been turned around a point. 2. Dilation; the figure has been enlarged. 3. Reflection or rotation; the figure has either been flipped over a line or turned around a point. 4. Translation; the figure has been slid down and to the left. 5. Dilation; the figure has been reduced. 6. Reflection; the figure has been flipped over a line. 7. Translation; the figure has been slid down and to the left.

34

¬tan1

A A ¬36.9° The measure of angle A is approximately 36.9. 8. tan A ¬5 8 A ¬tan15 8 A ¬32.0° The measure of angle A is approximately 32.0.

289

Chapter 9

8. Reflection or rotation; the figure has either been flipped over a line or turned around a point. 9. Reflection; the figure has been flipped over a line. 10. Reflection; the figure has been flipped over a line. 11. Rotation, reflection, and translation result in an image that is congruent to its preimage. They are isometries.

8.

y

A

B

x

O

B A

9-1 Page 467

9.

Reflections

y A

A


1. Sample Answer: The centroid of an equilateral triangle is not a point of symmetry. 2. Sample answer: W(3, 1), X(2, 3), Y(3, 3) and Z(3, 1) with reflected image W(1, 3), X(3, 2), Y(3, 3), Z(1, 3) y Z Y X

B C C 10.

y

D E

Z

W

x

O

B

F

x

O

x

O

F

X

E

W

D

3. Angle measure, betweenness of points, collinearity, and distance are four properties that are preserved in reflections. 4.

11.

y I

J

m

H

G

5. 2; The figure has 2 lines of symmetry, each passing through opposite vertices (at the tips). Yes; the figure has point symmetry with respect to its center. 6. 3; The figure has 3 lines of symmetry, each passing through the center, a vertex, and the midpoint of the side opposite the vertex. No; the figure has no common point of reflection and, thus, no point symmetry. 7. 6; The figure has 3 lines of symmetry at the tips of the 5-sided figures and 3 lines of symmetry between the 5-sided figures. The figure has point symmetry with respect to its center.

O

H

I

J

x

G 12. 1; The butterfly has 1 line of symmetry through its head and tail. No; the butterfly has no common point of reflection and, thus, no point symmetry. 13. 4; The leaf has 4 lines of symmetry: two passing between the leaves and two passing through their centers. Yes; the figure has point symmetry with respect to its center.

14. Looking at the tiger directly from the front, its face has one line of symmetry that goes down the center of the face vertically. No, the tiger face has no common point of reflection and, thus, no point symmetry.

Chapter 9

290

25. Draw perpendiculars from P, R, S, T, and U to line . Locate P, R, S, T, and U so that line is the perpendicular bisector of P P , R R , S S , T T , and U U . P, R, S, T, and U are the respective images of P, R, S, T, and U. Connect vertices P, R, S, T, and U.

Pages 467–469 Practice and Apply 15. X is on line , so it is its own reflection. Y is the image of W under a reflection in line . So, X Y is the image of W X under a reflection in line . 16. Z is on line , so it is its own reflection. Y is the image of W under a reflection in line . So, Y Z is the image of W Z under a reflection in line . 17. X and Z are on line , so they are their own reflections. W is the image of Y under a reflection in line . So, XZW is the image of XZY under a reflection in line . 18. T is on line m, so it is its own reflection. 19. U is on line m, so it is its own reflection. V is the image of Y under a reflection in line m. So, V U is the image of U Y under a reflection in line m. 20. V is the image of Y, Y is the image of V, and X is the image of W under a reflection in line m. So, VYX is the image of YVW under a reflection in line m. 21. T is the image of U under a reflection in point Z. 22. U is the image of T, V is the image of X, and Z is its own image under a reflection in point Z. So, UVZ is the image of TXZ under a reflection in point Z. 23. W is the image of Y, T is the image of U, and Z is its own image under a reflection in point Z. So, WTZ is the image of YUZ under a reflection in point Z. 24. Draw perpendiculars from A, B, C, D, E, and F to line . Locate A, B, C, D, E, and F so that line is the perpendicular bisector of A A , B B , C C , D D, E E , and F F . Points A, B, C, D, E, and F are the respective images of A, B, C, D, E, and F. Connect vertices A, B, C, D, E, and F. D C

R

S

T

T

R P

U U

P

26. Since W is on line , W is its own reflection. Draw segments perpendicular to line from X, Y, and Z. Locate X, Y, and Z so that is the perpendicular bisector of X X , Y Y , and Z Z . X, Y, and Z are the respective images of X, Y, and Z. Connect vertices W, X, Y, and Z. X

Y

W Z X Z Y

27. Plot rectangle MNPQ. Since Q Q passes through the origin, use the horizontal and vertical distances from Q to the origin to find Q. From Q to the origin is 2 units to the right and 3 units down. Q is located by repeating that pattern from the origin. Two units to the right and 3 units down yields Q(2, 3). Q(2, 3) → Q(2, 3) N(2, 3) → N(2, 3) P(2, 3) → P(2, 3) M(2, 3) → M(2, 3)

E

B

S

y

QN A

P M

F

A

PM

B

x

O

F

Q N

E

C

D

291

Chapter 9

28. Plot rectangle GHIJ. Since G G passes through the origin, use the horizontal and vertical distances from G to the origin to find G. From G to the origin is 2 units up and 2 units to the right. G is located by repeating that pattern from the origin. Two units up and 2 units to the right yields G(2, 2). G(2, 2) → G(2, 2) I(3, 3) → I(3, 3) H(2, 0) → H(2, 0) J(2, 4) → J(2, 4)

C

x

H x

G I J

y

29. Plot square QRST. Use the vertical grid lines to find a corresponding point for each vertex so that the x-axis is equidistant from each vertex and its image. Q(1, 4) → Q(1, 4) S(3, 2) → S(3, 2) R(2, 5) → R(2, 5) T(0, 1) → T(0, 1) y

C

32. Plot KLM. Use the vertical grid lines to find a corresponding point for each vertex so that the line y 2 is equidistant from each vertex and its image. For K(4, 0), the vertical distance to the line y 2 is 2. To plot K, move up 2 units on the vertical gridline so the image of K is K(4, 4). K(4, 0) → K(4, 4) L(2, 4) → L(2, 0) M(2, 1) → M(2, 3)

G H

B

D D

I

O

yx

y

O

y

J

B

K

L M M L

K x

O

R

Q 33. Plot FGH. To find FGH, use the horizontal grid lines to find a corresponding point for each vertex so that the y-axis is equidistant from each vertex and its image. F(1, 4) → F(1, 4) H(3, 2) → H(3, 2) G(4, 2) → G(4, 2)

S T x

OT

S Q

y

R

F F

30. Plot trapezoid DEFG. Use the horizontal grid lines to find a corresponding point for each vertex so that the y-axis is equidistant from each vertex and its image. E(2, 4) → E(2, 4) F(2, 1) → F(2, 1) D(4, 0) → D(4, 0) G(4, 3) → G(4, 3) y

E

G

H

x

F G

31. Plot BCD and the line y x. The slope of y x is 1. B B is perpendicular to y x, so its slope is 1. From B to the line y x, move up 2 units and to the left 3 units. From the line y x, move up 2 units and to the left 3 units to B(0, 5) B(5, 0) → B(0, 5) D(2, 1) → D(1, 2) C(2, 4) → C(4, 2)

Chapter 9

H

34. Plot XYZ. Use the horizontal grid lines to find a corresponding point for each vertex so that the line x 1 is equidistant from each vertex and its preimage. For X(1, 4), the horizontal distance to the line x 1 is 2. To plot X, move 2 units to the left of the line x 1 so the preimage of X is (3, 4). X(1, 4) → X(3, 4) Y(2, 2) → Y(4, 2) Z(2, 3) → Z(0, 3) Notice that Z is to the left of x 1 so its preimage is to the right of the line x 1.

D O

G

x

O

E

D F

G

292

41. Undo the reflections in turn. A(4, 7), B(10, 3), and C(6, 8). Reflection in the origin: multiply both coordinates by 1: (a, b) → (a, b): A(4, 7), B(10, 3), and C(6, 8). Reflection in the y-axis: multiply the x-coordinate by 1: (a, b) → (a, b): A(4, 7), B(10, 3), and C(6, 8). Reflection in the x-axis: multiply the y-coordinate by 1 (a, b) → (a, b): A(4, 7), B(10, 3), and C(6, 8). Undoing the transformations results in the triangle ABC. 42.

y

X

X

Y

Y

x

O

Z

Z

35. 2; The figure has two lines of symmetry, each passing through opposite vertices. Yes; the figure has point symmetry with respect to its center. 36. 8; The figure has eight lines of symmetry, each passing through opposite vertices. Yes; the figure has point symmetry with respect to its center. 37. 1; The figure has one line of symmetry, which passes horizontally through the center. No; the figure has no common point of reflection and, thus, no point symmetry. 38. The preimage and final image have the same shape and the same orientation.

m

cue ball eight ball reflected pocket

n

43. Consider point (a, b). Upon reflection in the origin, its image is (a, b). Upon reflection in the x-axis and then the y-axis, its image is (a, b) → (a, b). The images are the same. 44. The diamond has numerous lines of symmetry, including vertical and horizontal lines of symmetry. It has a point of symmetry at the center. 45. The diamond has a vertical line of symmetry, passing through its center. 46. The diamond has a vertical line of symmetry, passing through its center. 47. The diamond has a vertical line of symmetry and a horizontal line of symmetry. It has a point of symmetry at the center. 48. Sample answer: Reflections of the surrounding vistas can be seen in bodies of water. Answers should include the following. • Three examples of line symmetry in nature are the water’s edge in a lake, the line through the middle of a pin oak leaf, and the lines of a four leaf clover. • Each point above the water has a corresponding point in the image in the lake. The distance of a point above the water appears the same as the distance of the image below the water.

39. The preimage and final image have the same shape, but the final image is turned or rotated with respect to the preimage.

m

n

40. Apply the reflections in turn. D(1, 4), E(2, 8), F(6, 5), and G(3, 1). Reflection in the x-axis: Multiply the y-coordinates by 1: (a, b) → (a, b): D(1, 4), E(2, 8), F(6, 5), and G(3, 1). Reflection in the line y x: Interchange the x- and y- coordinates (a, b) → (b, a): D(4, 1), E(8, 2), F(5, 6), and G(1, 3). 8

F E 8

yx

y E

D

F

G

x G G 8

O

D

D 8

F

E

293

Chapter 9

49. D; x-axis reflection: (2, 5) → (2, 5) and y-axis reflection: (2, 5) → (2, 5) or reflection in the origin: (2, 5) → (2, 5) 50. B; a c ¬2a b 2c 25 45 ¬2(25) 18 2(45) 25 45 ¬158

53. BE is the measure of the median of the trapezoid. AF CD BE ¬ 2 48 32 ¬ 2

¬40 AF CD 54. BE ¬ 2 48 32 ¬ 2

¬40


BE CD XY ¬ 2

51. Given: Quadrilateral LMNP X, Y, Z, and W are midpoints of their respective sides. Prove: Y W and X Z bisect each other.

48 40 ¬ 2

¬44

AF CD 55. BE ¬ 2

y

M(2d, 2e) Y X

48 32 ¬ 2 ¬40

N(2a, 2c)

AF BE WZ ¬ 2

Z L(0, 0) W

40 32 ¬ 2 ¬36 56. mF mG mH ¬180 mF 53 71 ¬180 mF ¬56 Use the Law of Sines to write a proportion to find g.

P(2b, 0) x

Proof: 2a 2c 2d Midpoint Y of M N is , 2e 2 2 or (d a, e c). 2b 2a 0 Midpoint Z of N P is , 2c 2 or (a b, c). 2 2b 0 0 0 Midpoint W of P L is 2 , 2 or (b, 0).

sinF sinG f ¬g ¬fsinG g ¬ sinF 48 sin 53° g ¬ sin 56°

0 2d 0 2e M is 2, Midpoint X of L 2 or (d, e). dab ec0 Y is 2, Midpoint of W 2 or abd

ce 2, 2.

d a b c Z is , e Midpoint of X 2 2 or

g ¬46.2 Use the Law of Sines again to find the measure of the third side.

a b d e , c Z and W Y bisect each other. 2 2. X

sinF sinH f ¬h fsinH h ¬ sinF 48sin 71° h ¬ sin56°

52. Given: Isosceles trapezoid y D A B C H, J, K, and G D(b, c) J C(a b, c) are midpoints H K of their respective A(0, 0) G B(a, 0) x sides. Prove: GHJK is a rhombus. Proof: 2 2ab 2 c2 2

b a a 2 c HJ b ; 2 2 2 2 c ¬

h ¬54.7 Therefore, mF 56, g 46.2, and h 54.7. 57. mF mG mH ¬180 59 45 mH ¬180 mH ¬76 Use the Law of Sines to write a proportion to find f.

2a b 2 a 0 GK 2c 2 2

2

sinG sinF g ¬f gsinF f ¬ sinG 21sin 59° f ¬ sin45°

2 2ab

b a2 c2 ¬ ; 2

b 2 ab a c c ; b2 a2 ¬ 2 2 0 2a b a c KJ 2 2 c 2

HG

2

2

2

2

2

2

f ¬25.5

2

2 2ab a2 c2

b ¬ ; 2

HJ GK HG KJ, so H J G K H G K J and GHJK is a rhombus.

Chapter 9

294

Use the Law of Sines again to find the measure of the third side.

Page 472 Check for Understanding 1. Sample answer: A(3, 5) and B(4, 7); start at 3, count to the left to 4, which is 7 units to the left or 7. Then count up 2 units from 5 to 7 or 2. The translation from A to B is (x, y) → (x 7, y 2). 2. The properties that are preserved include betweenness of points, collinearity, and angle and distance measure. Since translations are composites of two reflections, all translations are isometries. Thus, all properties preserved by reflections are preserved by translations. 3. Allie; counting from the point (2, 1) to (1, 1) is right 3 and down 2 to the image. The reflections would be too far to the right. The image would be reversed as well. 4. Yes; GHI is a translation of ABC. DEF is the image of ABC when ABC is reflected in line m, and GHI is the image of DEF when DEF is reflected in line n. 5. No; quadrilateral WXYZ is oriented differently than quadrilateral NPQR. 6. This translation moved every point of the preimage 1 unit right and 3 units up. D(3, 4) → D(3 1, 4 3) or D(2, 1) E(4, 2) → E(4 1, 2 3) or E(5, 5) Graph D and E and connect. Graph D and E and connect. y E

h ¬28.8 Therefore, mH 76, f 25.5, and h 28.8. 58. We know two sides and the measure of the angle opposite one of the sides. Use the Law of Sines to find the measure of the second angle. F H sin sin f ¬ h fsinH sinF ¬ h fsinH h 14.5si 1 F ¬sin 13.n261°

F ¬sin1

F ¬74° So, mF 74. Use the Angle Sum Theorem to find the measure of angle G. mF mG mH ¬180 74 mG 61 ¬180 mG ¬45 Use the Law of Sines and a proportion to find g. H sin sinG h ¬g G hsin g ¬ sinH 13.2sin 45° g ¬ sin61°

g ¬10.7 Therefore, mF 74, mG 45, and g 10.7. 59.

Translations

9-2

G H sin sin g ¬ h gsinH h ¬ sinG 21 sin 76° h ¬ sin45°

E

d ¬ (x x1)2 (y2 y1)2 2 EF ¬ (2 3 )2 [0 (1 )]2 2 EF ¬ (1) 12 EF ¬ 2

60.

d ¬ (x x1)2 (y2 y1)2 2

D

FG ¬ (3 2 )2 (3 0)2

7. This translation moved every point of the preimage 3 units to the left and 4 units down. K(5, 2) → K(5 3, 2 4) or K(2, 6) L(3, 1) → L(3 3, 1 4) or L(6, 5) M(0, 5) → M(0 3, 5 4) or M(3, 1) Graph K, L, and M and connect to form KLM. Graph K, L, and M to form KLM.

2 32 FG ¬ 1 FG ¬ 10

61.

d ¬ (x x1)2 (y2 y1)2 2 2 (4 GH ¬ (5 3) 3)2

GH ¬ 22 12 GH ¬ 5 62.

x

O

D

d ¬ (x x1)2 (y2 y1)2 2

8

2 ( HE ¬ (3 5) 1 4)2

4

¬ (2)2 (5 )2

HE HE ¬ 29

M 8

4

M

O

L

8x

4 K

4

L 8

295

y

K

Chapter 9

8. 1 → 2 (x, y 3) 2 → 3 (x 4, y) 3 → 4 (x 4, y)

Pages 472–475

18. This translation moved every point of the preimage 2 units to the right and 1 unit down. E(0, 4) → E(0 2, 4 1) or E(2, 5) F(4, 4) → F(4 2, 4 1) or F(2, 5) G(0, 2) → G(0 2, 2 1) or G(2, 1) Plot the vertices of the preimage and the image and connect the respective vertices to form the preimage and the image.

Practice and Apply

9. Yes; it is one reflection after another with respect to the two parallel lines. 10. No; it is a reflection followed by a translation. 11. No; it is a reflection followed by a rotation. 12. No; it is a reflection followed by a translation. 13. Yes; it is one reflection after another with respect to the two parallel lines. 14. No; it is a reflection followed by a translation. 15. For each endpoint of P Q move left 3 units and up 4 units to find the image. Connect P and Q. 8 4

y

G G

F E

y

19. This translation moved every point of the preimage 5 units to the left and 3 units up. P(1, 4) → P(1 5, 4 3) or P(4, 7) Q(1, 4) → Q(1 5, 4 3) or Q(6, 7) R(2, 4) → R(2 5, 4 3) or R(7, 1) S(2, 4) → S(2 5, 4 3) or S(3, 1) Plot the vertices of the preimage and the image and connect the respective vertices to form the preimage and the image.

Q Q O

4

4

8

x

P

8 16. For each endpoint of A B move right 4 units and down 2 units. Connect A and B. A

E

F

P 4

x

O

8

y

P

Q

y

8

O

4

8x

4

4

B

B

P

Q

4 A

x

O

S

R

8

17. This translation moved every point of the preimage 1 unit to the right and 4 units up. M(2, 2) → M(2 1, 2 4) or M(1, 2) J(5, 2) → J(5 1, 2 4) or J(4, 6) P(0, 4) → P(0 1, 4 4) or P(1, 8) Plot the vertices of the preimage and the image and connect the respective vertices to form the preimage and the image.

S R 20. This translation moved every point of the preimage 4 units to the right and 3 units down. V(3, 0) → V(3 4, 0 3) or V(1, 3) W(3, 2) → W(3 4, 2 3) or W(1, 1) X(2, 3) → X(2 4, 3 3) or X(2, 0) Y(0, 2) → Y(0 4, 2 3) or Y( 4, 1) Z(1, 0) → Z(1 4, 0 3) or Z(3, 3) Plot the vertices of the preimage and the image and connect the respective vertices to form the preimage and the image.

y

P J

y

X

P

Y

W

J M O

x

x

Z

Y

W

M

Chapter 9

X

O

V

V

296

Z

21. As a translation, the bishop moves left 3 squares and down 7 squares. 22. Sample answers: pawn: up two squares; rook: left four squares; knight: down two squares, right 1 square; bishop: up three squares, right three squares; queen: up five squares; king: right 1 square 23. Four triangle lengths is equivalent to a translation of 48 in. right. 24. Two triangle lengths left and four triangle lengths up and left (60° angle above horizontal) form one leg and the hypotenuse of a right triangle. Use the Pythagorean Theorem to find the other leg (direction up). c2 ¬a2 b2 (4 12)2 ¬a2 (2 12)2 2304 ¬a2 576 1728 ¬a2 24 3 ¬a 41.6 ¬a The translation is 24 3 41.6 in. up and 24 in. left. 25. The red line represents a translation of six triangle lengths right and four triangle heights down. Use the Pythagorean Theorem to find the triangle height. c2 ¬a2 b2 122

¬a2

8

y

W T

4

y=1

T

8 4

Y Y 4

8 x

W

4

T

8

y = 4

Y

Examine: Notice that the image of W(7, 4) is W(7, 6) or point D. The line y 1 is equidistant from these points. The image of Y(9, 0) is Y(9, 2) or G. Again, the line y 1 is equidistant from these points. So, two possible parallel lines are y 4 and y 1. 27. This translation moved every point of the preimage 2 units to the right and 4 units down. P(3, 2) → P(3 2, 2 4) or P(1, 6) Q(1, 4) → Q(1 2, 4 4) or Q(1, 0) R(2, 2) → R(2 2, 2 4) or R(4, 6) y

Q

Q x

O

2 12 2

R P

144 ¬a2 36 108 ¬a2 6 3 ¬a Six lengths: 6(12) 72 Four heights: 4(6 3 ) 24 3 41.6 The translation is 72 in. right and 24 3 41.6 in. down. 26. Sample answer: Explore: We are looking for two parallel lines such that TWY is reflected over each line to result in the image BDG. Plan: Once we choose any line to be the first parallel line, there is only one possible line for the second parallel line. Solve: Choose y 4 for the first parallel line. Use the vertical grid lines to determine the vertices of the image that are the same distance from y 4 as the preimage. Since the y-coordinate of W is 4, W is its own image. T(3, 7) → T(3, 1) Y(9, 8) → Y(9, 0) Now we need to find a line such that a reflection over that line has an image of BDG. We are looking for a line that is equidistant between TWY and BDG. We are only looking at the y-coordinates. T(3, 1) → B(3, 3). The distance between the y-coordinates is 1 3 4 so the parallel line that lies halfway between is 2 units above the line y 1 or y 1.

P

R

28. First reflect RST in the line y 2. Use the vertical grid lines to find images of the vertices that are the same distance from y 2 as the preimage. R(4, 1) → R(4, 5) R S(1, 3) → S(1, 1) S, T y T(1, 1) → T(1, 3) x

R

Next reflect RST over the line y 2 to get RST. R(4, 5) → R(4, 9) S(1, 1) → S(1, 5) T(1, 3) → T(1, 7)

T, S

y

S

T O

x

R S

T R

297

Chapter 9

80 % 33. 9 8.89% per person

29. To find the image, “undo” the translation. To undo (x 4, y 5), add 4 to the x-coordinate and subtract 5 from the y-coordinate. A(8, 5) → A(8 4, 5 5) or A(4, 0) B(2, 7) → B(2 4, 7 5) or B(6, 2) C(3, 1) → C(3 4, 1 5) or C(7, 4)

78 % 8 9.75% per person 70 % 7 10% per person 62 % 7 8.86% per person

No; the percent per figure is different in each category. 34. Sample answer: Every time a band member takes a step, he or she moves a fixed amount in a certain direction. This is a translation. Answers should include the following. • When a band member takes a step forward, backward, left, right, or on a diagonal, this is a translation. • To move in a rectangular pattern, the band member starting at (0, 0) could move to (0, 5). Moving from (0, 5) to (4, 5), from (4, 5) to (4, 0) and from (4, 0) back to the origin, the band member would have completed the rectangle. 35. Translations and reflections preserve the congruences of lengths and angles. The composition of the two transformations will preserve both congruences. Therefore, a glide reflection is an isometry. 36. First, find the vertices of the image after the translation (x, y) → (x, y 2). D(4, 3) → (4, 3 2) or (4, 1) E(2, 2) → (2, 2 2) or (2, 4) F(0, 1) → (0, 1 2) or (0, 1) Now reflect the image in the y-axis. Use the formula (a, b) → (a, b). (4, 1) → D(4, 1) (2, 4) → E(2, 4) (0, 1) → F(0, 1)

y

B

8 A

4 A 4

8

B O

8x

C

4

C

30. In order to find the coordinates of H and N we find the transformation from vertex F to vertex M. F(3, 9) → M(4, 2) The translation in the x-direction is 1 unit to the right. The translation in the y-direction is 7 units down. G(1, 4) → N(x1, y1) → N(1 1, 4 7) or N (0, 3) H(x2, y2) → P(6, 3) Undo the transformation by subtracting one and adding 7. So the coordinates of H are H(6 1, 3 7) or H(5, 4). y

F

G H M

y O

x

N

P

D D

The coordinate form of the translation is (x, y) → (x 1, y 7). 31. The categories that show a boy-girl-boy unit translated within the bar are “more brains” and “more free time”. 32. “More friends” and “more athletic ability” are the categories that show a boy-girl-boy unit reflected (about a vertical line) within the bar.

Chapter 9

F F

x

E E

298

37. First, find the vertices of the image after the translation (x, y) → (x 3, y). A(3, 2) → (3 3, 2) or (0, 2) B(1, 3) → (1 3, 3) or (2, 3) C(2, 1) → (2 3, 1) or (5, 1) Now reflect the image over the line y 1. Use the horizontal grid lines to find the vertices of ABC such that each vertex of the image is the same distance from the line y 1 as its preimage. (0, 2) → A(0, 4) (2, 3) → B(2, 5) (5, 1) → C(5, 3)

41. Draw perpendiculars from P, R, S, T, and U to line m. Locate P, R, S, T, and U so that line m is the perpendicular bisector of P P , R R , S S , T T , and U U . Points P, R, S, T, and U are the respective images of P, R, S, T, and U. Connect vertices P, R, S, T, and U. S T U R P

B

y

m

P

A

R

y=1

C

U T

C

x

S

A B

42. Since D is on line m, D is its own reflection. Draw perpendiculars from E, F, G, H, and I to line m. Locate E, F, G, H, and I so that line m is the perpendicular bisector of E E , F F , G G , H H , and II. Points E, F, G, H, and I are the respective images of E, F, G, H, and I. Connect vertices D, E, F, G, H, and I.

38. C; X(5, 4) → X(3, 1) X(5 2, 4 3) So, (x, y) → (x 2, y 3). Y(3 2, 1 3) ¬Y(1, 4) Z(0 2, 2 3) ¬Z(2, 1) y y x2 x1 1 5 ¬ 2 (2) 6 ¬ 4 ¬3 2

2 1 39. A; m ¬

H G

I

E

Page 475

D


G

40. Draw perpendiculars from A, B, C, D, and E to line m. Locate A, B, C, D, and E so that line m is the perpendicular bisector of A A , B B , C C , D D , and E E . Points A, B, C, D, and E are the respective images of A, B, C, D, and E. Connect vertices A, B, C, D, and E.

A

C

F 43. The top and bottom segments of the trapezoid are parallel, so the y-coordinate of Q is the same as that of R, c. The x-coordinate of Q plus the x-coordinate of R equals the x-coordinate of S. x b ¬a x ¬a b So, Q(?, ?) Q(a b, c). T is at the origin, so T(?, ?) T(0, 0). 44. Opposite sides of a parallelogram are congruent and parallel. So, the y-coordinate of B is b and that of D is 0. The x-coordinate of B plus the x-coordinate of D equals the x-coordinate of C. x d ¬a d x ¬a So, B(?, ?) B(a, b) and D(d, ?) D(d, 0).

C

E D

E

B

H E

B

A

m

I

F

D m

299

Chapter 9

x 4 ¬x 2 6 ¬2x 3 ¬x y ¬(3) 4 ¬3 4 ¬1 The point of intersection is (3, 1). Find the distance between the two points of intersection, (0, 4) and (3, 1). d ¬ (x2 x1)2 (y2 y1)2 2 ¬ (3 0) [1 (4)]2 ¬ 99 ¬3 2 The distance between the lines is 3 2.

45. Find the opposite side of the triangle, y. y tan 45° ¬ 6

46. 47. 48. 49. 50.

51.

52.

6tan 45° ¬y 6 ¬y Six yards is 18 feet. So, the height of the tree is 5 18 or 23 ft. A certain shopper is not greeted when he walks through the door. You did not fill out an application. y6 The two lines are not parallel. x 2 and x 5 are vertical lines. The distance between them can be measured along any horizontal segment connecting them. The distance is 5 (2) 7. y 6 and y 1 are horizontal lines. The distance between them can be measured along any vertical segment between them. The distance is 6 (1) 5. Let line be y 2x 3 and line m be y 2x 7. The slope of the parallel lines is 2. The slope of a line perpendicular to the parallel lines is the

54. 30

55. 45

56.

1 opposite reciprocal of 2, or 2. Use the y-intercept

52

of line m, (0, 7), as one of the endpoints of the perpendicular segment, P. Find P. P: y y1 ¬m(x x1)

57.

1

y (7) ¬2(x 0)

60

y 7 ¬1 2x 1 y ¬2x 7

58. 105

Solve the system of the equations of lines P and to find where they intersect.

59.

1 2 x 7 ¬2x 3 x 14 ¬4x 6 5x ¬20 x ¬4 (4) 7 y ¬1 2 ¬2 7 ¬5 The point of intersection is (4, 5). Find the distance between the two points of intersection, (0, 7) and (4, 5). d ¬ (x2 x1)2 (y2 y1)2

9-3

Rotations

Page 477 Geometry Software Investigation: Reflections in Intersecting Lines 1. 2. 3. 4.

See students’ figures. The transformation is a rotation about P. See students’ work. See students’ work. The angle measure should be twice the measure of the acute angle formed by the intersecting lines. 5. See students’ work. The angle measures should be the same as mAPA in Exercise 4. 6. Sample answer: The measure of the angle of rotation is twice the measure of the acute angle formed by the intersecting lines.

¬ (4 0)2 [5 (7)]2 ¬ 16 4 ¬2 5 The distance between the lines is 2 5 . 53. Let line be y x 2 and line m be y x 4. The slope of the parallel lines is 1. The slope of a line perpendicular to the parallel lines is the opposite reciprocal of 1, or 1. Use the y-intercept of line m, (0, 4), as one of the endpoints of the perpendicular segment, P. Find P. P: y y1 ¬m(x x1) y (4) ¬1(x 0) y 4 ¬x y ¬x 4 Solve the system of the equations of lines P and to find where they intersect.

Chapter 9

150

300

Pages 478–479

5. First reflect parallelogram ABCD in line . Next, reflect the image in line m. Parallelogram ABCD is the image of parallelogram ABCD under reflections in lines and m.


1. Sample answer: y

C B

m

A x

O 90

C

A

A

B

D

B C

B

ABC has vertices A(1, 0), B(4, 2), and C(2, 3). ABC has vertices A(0, 1), B(2, 4), and C(3, 2). For a clockwise rotation of 90 degrees about the origin, (x, y) → (y, x).

B

A

C D

B

y

C

C A

B C

A

90

O

A

6. First reflect quadrilateral DEFG in line . Since E and F are on , each point is its own image. Next, reflect the image in line m. Quadrilateral DEF G is the image of quadrilateral DEFG under reflections in lines and m.

x

ABC has vertices A(1, 0), B(4, 2), and C(2, 3). ABC has vertices A(0, 1), B(2, 4), and C(3, 2). For a counterclockwise rotation of 90 degrees about the origin, (x, y) → (y, x). 2. A rotation image can be found by reflecting the image in a line, then reflecting that image in a second of two intersecting lines. The second method is to rotate each point of the given figure using the angle of rotation twice the angle formed between the intersecting lines. Use the intersection point of the two lines as the point of rotation. 3. Both translations and rotations are made up of two reflections. The difference is that translations reflect across parallel lines and rotations reflect across intersecting lines. 4. Draw a segment from G to B. Use a protractor to measure a 60° angle counterclockwise with G B as . Use a compass to copy G one side. Draw GX B . Name the segment G onto GX B . Repeat with points C and D. BCD is the image of BCD under a 60° counterclockwise rotation about point G.

D

E m

G D F

G

G D F E

7. First graph X Y . Draw a segment from the origin O to point X. Use a protractor to measure a 45° angle clockwise with O X as one side. Draw OR. . Name the Use a compass to copy O X onto OR segment O X . Repeat with point Y. X Y is the image of X Y under a 45° clockwise rotation about the origin. y

D

C

D

X ( 5 , 8 )

X

D B G

C

Y(0, 3)

60

Y

45 O

x

B

301

Chapter 9

8. First graph PQR. Draw a segment from the origin O to point P. Use a protractor to measure a 90° angle counterclockwise with O P as one side. Draw OX. Use a compass to copy O P onto OX. Name the segment O P . Repeat with points Q and R. PQR is the image of PQR under a 90° counterclockwise rotation about the origin.

110

C

P (8, 1) 90 12 4 O 4

R (7, 4)

8

D

F B C

P(1, 8) y 4

D

Q (2, 4) 4

8

E

13. Draw a segment from Q to M. Use a protractor to measure a 180° angle counterclockwise with Q M as one side. Draw QX. Use a compass to copy Q M onto QX. Name the segment Q M . Repeat with points N and P. MNP is the image of MNP under a 180° counterclockwise rotation about point Q.

x

Q (4, 2) R(4, 7)

M

9. The regular hexagon has rotational symmetry of order 6 because there are 6 rotations less than 360° (including 0 degrees) that produce an image indistinguishable from the original. 360° magnitude ¬ ord er

P

180˚

N

P

M

14. First graph XYZ and point P. Draw a segment from point P to point X. Use a protractor to measure a 90° angle counterclockwise with P X as one side. Draw PR. Use a compass to copy P X . Name the segment P onto PR X . Repeat with points Y and Z. XYZ is the image of XYZ under a 90° counterclockwise rotation about point P.

36 0° ¬ 8

¬45° The magnitude of the symmetry is 45°. 11. The left, center, and right fans have rotational symmetry of orders 5, 4, and 3, respectively, because there are 5, 4, and 3 rotations less than 360° (including 0 degrees) that produce images indistinguishable from the originals. The magnitude of the symmetry is given by 360° ord er . So, the magnitudes of the symmetries for the left, center, and right fans are 72°, 90°, and 120°, respectively.

Y

y Z

P

X

Z Y 90 x

o

X 15. First graph RST and point P. Draw a segment from point P to point R. Use a protractor to measure a 90° angle clockwise with P R as one . Use a compass to copy P side. Draw PX R onto . Name the segment P PX R . Repeat with points S and T. RST is the image of RST under a 90° clockwise rotation about point P.

Practice and Apply

y

12. Draw a segment from R to B. Use a protractor to measure a 110° angle counterclockwise with R B as one side. Draw RX. Use a compass to copy R B onto RX. Name the segment R B . Repeat with points C, D, E, and F. Pentagon BCDEF is the image of pentagon BCDEF under a 110° counterclockwise rotation about point R.

R

T

90

T R O

S

Chapter 9

N Q

36 0° ¬ 6 ¬60° The magnitude of the symmetry is 60°. 10. The regular octagon has rotational symmetry of order 8 because there are 8 rotations less than 360° (including 0 degrees) that produce an image indistinguishable from the original. 360° magnitude ¬ ord er

Pages 479–481

E

F

R

B

302

S x

16. The Ferris wheel has rotational symmetry of order 20 because there are 20 rotations less than 360° (including 0 degrees) that produce an image indistinguishable from the original.

23.

y L

M

M

36 0° magnitude ¬ order 36 0° ¬ 20

L

¬18° The magnitude of the symmetry is 18°. 17. From Exercise 16, the magnitude of the symmetry is 18°. Seat 1 is moved 4 positions, or 4(18°) 72°. 18. From Exercise 16, the magnitude of the symmetry is 18°. Divide 144° by the magnitude of the rotational symmetry.

K

Reflection in line y x: K(5, 0) → K(0, 5) L(2, 4) → L(4, 2) M(2, 4) → M(4, 2) Reflection in x-axis: K(0, 5) → K(0, 5) L(4, 2) → L(4, 2) M(4, 2) → M(4, 2) The angle of rotation is 90° clockwise.

14 4° 18° 8 positions

Seat 1 is moved 8 positions, or to the original position of seat 9. 19.

Y

m

K x

O

24.

y

Z

Y

t X

Z X

X'

X x

O

Z' Y'

20.

Z Y Reflection in line y x: X(5, 0) → X(0, 5) Y(3, 4) → Y(4, 3) Z(3, 4) → Z(4, 3) Reflection in line y x: X(0, 5) → X(5, 0) Y(4, 3) → Y(3, 4) Z(4, 3) → Z(3, 4) The angle of rotation is 180°.

S' P'

t

m

R' Q'

R S Q P 25.

21.

J

K

N

L

M

t

y ( 3 , 1)

30˚ (2, 0)

M' L'

x

N' J' K'

m

22.

x 2cos 30° 3 y 2sin 30° 1 The coordinates of the image are ( 3 , 1).

y

U V T O

V

T x

U Reflection in y-axis: T(4, 0) → T(4, 0) U(2, 3) → U(2, 3) V(1, 2) → V(1, 2) Reflection in x-axis: T(4, 0) → T(4, 0) U(2, 3) → U(2, 3) V(1, 2) → V(1, 2) The angle of rotation is 180°.

303

Chapter 9

26. The CD changer has rotational symmetry of order 5 because there are 5 rotations less than 360° (including 0 degrees) that produce an image indistinguishable from the original.

44. Reflection is an indirect isometry because the image of the transformed figure cannot be found by moving it intact within the plane. 45. Translation is a direct isometry because the image of the transformed figure is found by moving it intact within the plane. 46. Rotation is a direct isometry because the image of the transformed figure is found by moving it intact within the plane.

360° magnitude ord er 36 0° ¬ 5

27. 28. 29. 30. 31. 32.

¬72° The magnitude of the symmetry is 72°. Yes; it is a proper successive reflection with respect to the two intersecting lines. Yes; it is a proper successive reflection with respect to the two intersecting lines. Yes; the teacups are rotating. Yes; the scrambler is rotating. No; the roller coaster is not rotating. The letters H, I, N, O, S, X, and Z produce the same letter after being rotated 180°.

Page 482 Maintain Your Skills 47. Yes; it is one reflection after another with respect to the two parallel lines. 48. No; it is a rotation followed by a reflection with respect to line a. 49. Yes; it is one reflection after another with respect to the two parallel lines. 50. C is the image of A in a reflection across line p. G is its own image. So, the image of A G reflected across line p is C G . 51. C is the image of F reflected across point G. 52. H is the image of E reflected across line q. G is its own image. So, the image of G E reflected across line q is G H . 53. A and F are the images of C and D, respectively, in a reflection across line p. G is its own image. So, the image of CGD reflected across line p is AGF. 54. Q R P S because opposite sides are parallel. 55. P T T R because diagonals bisect each other. 56. SQR QSP because alternate interior angles are congruent. 57. QPS QRS because opposite angles are congruent. 58. Let y be the opposite side of the right triangle formed by the eye of the surveyor, the top of the building, and the side of the building at the eye level of the surveyor (100 meters from the eye).

36 0° 33. 40°/reflection 9 reflections 34. Angles of rotation with measures 90 or 180 would be easier on a coordinate plane because of the grids used in graphing. 35. In each case, y-coordinates become x-coordinates and the opposite of the x-coordinates become y-coordinates, or (x, y) → (y, x). 36. The 80° clockwise rotation and then 150° counterclockwise rotation about the origin is equivalent to a 70° counterclockwise rotation. 37. Any point on the line of reflection is invariant. 38. The center of rotation is the only invariant point. 39. There are no invariant points. Every point is translated a units in the x-direction and b units in the y-direction. 40. Sample answer: The Tilt-A-Whirl sends riders tipping and spinning on a circular track. Answers should include the following. • The Tilt-A-Whirl shows rotation in two ways. The cars rotate about the center of the ride as the cars go around the track. Each car rotates around a pivot point in the car. • Answers will vary but the Scrambler, Teacups, and many kiddie rides use rotation.

tan 23° ¬y 100

360°

41. B; the central angle of the octagon is 8 45°. The triangle is moved three positions clockwise, or 3(45)° 135°.

59.

1 2 1 2 42. D; x 2 5 y and y 3 z, so x 5 3 z 15 z, or 15 15 z 2 x 2 (6) 45.

43.

60. Transformation reflection translation rotation angle measure

yes

yes

yes 61.

betweenness of points

yes

yes

yes

orientation

no

yes

no

collinearity

yes

yes

yes

distance measure

yes

yes

yes

Chapter 9

62.

100tan 23° ¬y 42.45 ¬y So, the height of the building is about 42.45 1.55 44.0 m. Use the triangle inequality. ? 6 8 16 14 16 no Use the triangle inequality. ? 12 17 20 29 20 yes Use the triangle inequality. ? 22 23 37 45 37 yes 180a 360 36 0 a ¬ 180

a ¬2

304

63. 180a 90b ¬360 2a b ¬4 b ¬2a 4 Use a table. a b 0

4

1

2

2

0

Page 482 Practice Quiz 1 1. For a reflection in the origin, (a, b) → (a, b) D(1, 1) → D(1, 1) E(1, 4) → E(1, 4) F(3, 2) → F(3, 2) y E

F D

Three values are (0, 4), (1, 2), and (2, 0). 64. 135a 45b ¬360 3a b ¬8 b ¬3a 8 Use a table. a

b

0

8

1

5

2

2

O

E 2. For a reflection in the line y x, (a, b) → (b, a) A(0, 2) → A(2, 0) B(2, 2) → B(2, 2) C(3, 0) → C(0, 3) D(1, 1) → D(1, 1) y


b

0

12

1

8

2

4

3

0

C

b

0

6

1

3

2

0

b

0

12

1

6

2

0

B B

O

A

C x

D

3. The translation moved each endpoint 3 units to the left and 4 units up. P(1, 4) → P(1 3, 4 4) or P(2, 0) Q(4, 1) → Q(4 3, 1 4) or Q(1, 3) y

Q

O x

P

Q P


A D

Four values are (0, 12), (1, 8), (2, 4), and (3, 0). 66. 180a 60b ¬360 3a b ¬6 b ¬3a 6 Use a table. a

x

D

F

4. The translation moved each vertex 1 unit to the right and 4 units down. K(2, 0) → K(2 1, 0 4) or K(1, 4) L(4, 2) → L(4 1, 2 4) or L(3, 2) M(0, 4) → M(0 1, 4 4) or M(1, 0) y

M L O

K

Three values are (0, 12), (1, 6), and (2, 0).

M x

L K

305

Chapter 9

5. The 36-horse carousel has rotational symmetry of order 36 because there are 36 rotations less than 360° (including 0 degrees) that produce an image indistinguishable from the original.

4. Let m1 represent one interior angle of the regular decagon. Use the Interior Angle Formula. 180(n 2) m1 n 180(10 2) ¬ 10

36 0° magnitude ¬ order

¬144 Since 144 is not a factor of 360, a decagon will not tessellate the plane. 5. Let m1 represent one interior angle of the regular decagon. Use the Interior Angle Formula.

36 0° ¬ 36 ¬10° The magnitude of the symmetry is 10°.

9-4

180(n 2) m1 n

Tessellations

180(30 2) ¬ 30

¬168 Since 168 is not a factor of 360, a decagon will not tessellate the plane. 6. Yes; Use the algebraic method to determine whether a semi-regular tessellation can be created using squares and triangles of side length 1 unit. Each interior angle of a square measures 90°, and each interior angle of a triangle measures 60°. Find whole number values for h and t so that 90h 60t 360. Let h 2. 90(2) 60t ¬360 180 60t ¬360 60t ¬180 t ¬3 When h 2 and t 3, there are two squares with three triangles at each vertex.

Page 483 Geometry Activity: Tessellations of Regular Polygons 1. equilateral triangle, square, and hexagon 2. The measure of an interior angle of an equilateral triangle is 60; of a square, 90; of a hexagon, 120. The sum of the measures of the angles at each vertex must be 360. The expressions are: 6(60) 360; 4(90) 360; 3(120) 360. 3. The measure of an interior angle of a pentagon is 108; of a heptagon, about 128.57; of an octagon, 135. 36 0 36 0 36 0 1 2 108 3 3 ; 128.57 2.8; 135 2 3

108, 128.57, and 135 are not factors of 360, so the pentagon, the heptagon, and the octagon do not tessellate the plane. Regular Polygon

Measure of Does It One Interior Angle Tessellate?

triangle

60

yes

square

90

yes

pentagon

108

no

hexagon

120

yes

heptagon

128.57

no

135

no

octagon

60 60

60

90 90

7. Yes; Use the algebraic method to determine whether a semi-regular tessellation can be created using squares and octagons of side length 1 unit. Each interior angle of a square measures 90°, and each interior angle of an octagon measures

4. If a regular polygon has an interior angle with a measure that is a factor of 360, then the polygon will tessellate the plane.

180(8 2) or 135°. 8

Find whole number values for h and t so that 90h 135t 360. Let h 1. 90(1) 135t ¬360 90 135t ¬360 135t ¬270 t ¬2 When h 1 and t 2, there is one square with two octagons at each vertex.

Pages 485–486 Check for Understanding 1. Semi-regular tessellations contain two or more regular polygons, but uniform tessellations can be any combination of shapes. 2. Sample answer:

90 135 135

3. The figure used in the tessellation appears to be a trapezoid, which is not a regular polygon. Thus, the tessellation cannot be regular.

Chapter 9

306

8. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. 9. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. 10. Each “postage stamp” is a square that has been tessellated and 90 is a factor of 360. It is a regular tessellation since only one polygon is used.

Pages 486–487

16. No; let m1 represent one interior angle of the regular 36-gon. Use the Interior Angle Formula. 180(n 2) m1 n 180(36 2) ¬ 36

¬170 Since 170 is not a factor of 360, a 36-gon will not tessellate the plane. 17. No; A rhombus is not a regular polygon, so a semiregular tessellation cannot be created from regular octagons and rhombi. 18. Yes; Use the algebraic method to determine whether a semi-regular tessellation can be created using regular dodecagons and equilateral triangles of side length 1 unit. Each interior angle of a dodecagon measures

Practice and Apply

180(12 2) or 150°, and each interior angle of an 12

11. No; let m1 represent one interior angle of the regular nonagon. Use the Interior Angle Formula.

equilateral triangle measures 60°. Find whole number values for h and t so that 150h 60t 360. Let h 2. 150(2) 60t ¬360 300 60t ¬360 60t ¬60 t ¬1 When h 2 and t 1, there are two dodecagons with one triangle at each vertex.

180(n 2) m1 n 180(9 2) ¬ 9

¬140 Since 140 is not a factor of 360, a nonagon will not tessellate the plane. 12. Yes; let m1 represent one interior angle of the regular nonagon. Use the Interior Angle Formula. 180(n 2) m1 n 180(6 2) ¬ 6

¬120 Since 120 is a factor of 360, a hexagon will tessellate the plane. 13. Yes; let m1 represent one interior angle of the equilateral triangle. Use the Interior Angle Formula.

60

150 150

180(n 2) m1 n

19. Yes; Use the algebraic method to determine whether a semi-regular tessellation can be created using regular dodecagons, squares, and equilateral triangles of side length 1 unit. Each interior angle of a dodecagon measures

180(3 2) ¬ 3

¬60 Since 60 is a factor of 360, an equilateral triangle will tessellate the plane. 14. No; let m1 represent one interior angle of the regular dodecagon. Use the Interior Angle Formula.

180(12 2) or 150°, and each interior angle of 12

squares and equilateral triangles measures 90° and 60°, respectively. Find whole number values for h, s, and t so that 150h 90s 60t 360. Let h 1 and s 1. 150(1) 90(1) 60t ¬360 150 90 60t ¬360 60t ¬120 t ¬2 When h 1, s 1, and t 2, there are one dodecagon, one square, and two triangles at each vertex. 60

180(n 2) m1 n 180(12 2) ¬ 1 2

¬150 Since 150 is not a factor of 360, a dodecagon will not tessellate the plane. 15. No; let m1 represent one interior angle of the regular 23-gon. Use the Interior Angle Formula. 180(n 2) m1 n 180(23 2) ¬ 2 3

60

¬164.3 Since 164.3 is not a factor of 360, a 23-gon will not tessellate the plane.

307

90 150

Chapter 9

20. No; Use the algebraic method to determine whether a semi-regular tessellation can be created using regular heptagons, squares, and equilateral triangles of side length 1 unit. Each interior angle of a heptagon measures

23. yes; tessellation:

180(7 2) 900 7 7 or approximately 128.6°, and

each interior angle of squares and equilateral triangles measures 90° and 60°, respectively. Find whole number values for h, s, and t so that

The pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. 24. No; use the algebraic method to determine whether the combination of a regular pentagon and a square with equal side length tessellates the plane. Each interior angle of a square measures 90°, and each interior angle of a pentagon measures

90 0 7 h 90s 60t 360.

Let s 1 and t 1.

90 0 7 h 90(1) 60(1) 360 90 0 7 h 90 60 ¬360 90 0 7 h ¬210

h ¬1.63

Let s 1 and t 2. 90 0 7 h 90(1) 60(2) 360 90 0 7 h 90 120 ¬360 90 0 7 h ¬150

180(5 2) 5 or 108°.

h ¬1.17

Let s 2 and t 1. 90 0 7 h 90(2) 60(1) 360 90 0 7 h 180 60 ¬360 90 0 7 h ¬120

h ¬0.93 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from regular heptagons, squares, and equilateral triangles. 21. yes; tessellation:

The pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. 22. yes; tessellation:

25.

26.

27.

The pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles.

Chapter 9

28.

308

Find whole number values for h and t so that 90h 108t 360. Let h 1. 90(1) 108t 360 90 108t ¬360 108t ¬270 t ¬2.5 Let h 2. 90(2) 108t 360 180 108t ¬360 108t ¬180 t ¬1.67 Let h 3. 90(3) 108t 360 270 108t ¬360 108t ¬90 t ¬0.83 No combination of a regular pentagon and a square with equal side length can be formed such that the total of the measures of the angles at a vertex is 360°. So, the combination does not tessellate the plane. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is also regular since it is formed by only one type of regular polygon. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is also semi-regular since more than one regular polygon is used.

360(12 2) 180(10) 18 0 18 0 41. A; 12 12 2(12) 12

29. The tessellation is semi-regular since more than one regular polygon is used. The tessellation is also uniform because at every vertex there is the same combination of shapes and angles. 30. Always; the sum of the measures of the interior angles of a triangle is 180°. If each angle is used twice at each vertex, the sum of the angles is 360°. 31. Never; semi-regular tessellations have the same combination of shapes and angles at each vertex like uniform tessellations. The shapes for semiregular tessellations are just regular. 32. Sometimes; when the combination of shapes are regular polygons, then the uniform tessellation becomes semi-regular. 33. Always; the sum of the measures of the angles of a quadrilateral is 360°. So if each angle of the quadrilateral is rotated at the vertex, then that equals 360 and the tessellation is possible. 34. Never; the measure of an interior angle is

180 1800 ¬ 12 162 0 ¬ 12

¬135

Page 488 Maintain Your Skills 42. First graph ABC and point P. Draw a segment from point P to point A. Use a protractor to measure a 90° angle counterclockwise with P A as . Use a compass to copy P A one side. Draw PR . Name the segment P onto PR A . Repeat with points B and C. ABC is the image of ABC under a 90° counterclockwise rotation about point P. y

A (1, 12) 8

180(16 2) or 157.5, which is not a factor of 360. 16

B (6, 6)

90 4 PO

35. Yes; the measure of each angle is 90°. 36. None of these; the tessellation is not uniform because the number of angles at the vertices varies. It is not regular since more than one polygon is used. It is not semi-regular since not all of the polygons are regular. 37. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is also regular since only one regular polygon is used. 38. Sample answers:

A x

C

4 C

8

(2, 0)

B 43. First graph DEF and point P. Draw a segment from point P to point D. Use a protractor to D as one measure a 90° angle clockwise with P . Use a compass to copy P D onto side. Draw PR PR. Name the segment P D . Repeat with points E and F. DEF is the image of DEF under a 90° clockwise rotation about point P. y F

D 90

x

135 135 90

O

F (8, 1) 90

90

P

E D (7, 5)

E (2, 5)

44. First graph parallelogram GHIJ and point P. Draw a segment from point P to point G. Use a protractor to measure a 90° angle . G as one side. Draw PR counterclockwise with P . Name the G onto PR Use a compass to copy P segment P G . Repeat with points H, I, and J. Parallelogram GHIJ is the image of GHIJ under a 90° counterclockwise rotation about point P.

The measures are 90°, 90°, 90°, 135°, and 135°. The tessellation is not regular since the pentagons are not regular and it is not uniform since the number of angles at the vertices varies. 39. Sample answer: Tessellations can be used in art to create abstract art. Answers should include the following. • The equilateral triangles are arranged to form hexagons, which are arranged adjacent to one another. • Sample answers: kites, trapezoids, isosceles triangles

y

G

x O

J

G (7, 2)

180(n 2) 40. C; interior angle n

J

(4, 4)

180(9 2) ¬ 9

I

90

P H H

(2, 4)

I (1, 6)

¬140

309

Chapter 9

45. First graph rectangle KLMN and point P. Draw a segment from point P to point K. Use a protractor to measure a 90° angle counterclockwise with P K . Use a compass to copy P as one side. Draw PR K . Name the segment P onto PR K . Repeat with points L, M, and N. Rectangle KLMN is the image of KLMN under a 90° counterclockwise rotation about point P.

M (2, 9)

50. 12, 16, 20 Since the measure of the longest side is 20, 20 must be c, and a and b are 12 and 16. a2 b2 ¬c2 122 162 ¬202 144 256 ¬400 400 ¬400 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple. 51. 9, 10, 15 Since the measure of the longest side is 15, 15 must be c, and a and b are 9 and 10. a2 b2 ¬c2 92 102 ¬152 81 100 ¬225 181 ¬225 Since 181 225, segments with these measures cannot form a right triangle. Therefore, they do not form a Pythagorean triple. 52. 2.5, 6, 6.5 Since the measure of the longest side is 6.5, 6.5 must be c, and a and b are 2.5 and 6. a2 b2 ¬c2 2.52 62 ¬6.52 6.25 36 ¬42.25 42.25 ¬42.25 Since 42.25 42.25, segments with these measures form a right triangle. However, only one of the three numbers is a whole number. Therefore, they do not form a Pythagorean triple. 53. 14, 14 3, 28 Since the measure of the longest side is 28, 28 must be c, and a and b are 14 and 14 3 . a2 b2 ¬c2 142 (14 3 )2 ¬282 196 588 ¬784 784 ¬784 Since 784 784, segments with these measures form a right triangle. However, only two of the three numbers are whole numbers. Therefore, they do not form a Pythagorean triple. 54. 14, 48, 50 Since the measure of the longest side is 50, 50 must be c, and a and b are 14 and 48. a2 b2 ¬c2 142 482 ¬502 196 2304 ¬2500 2500 ¬2500 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple.

y

8

L

4

(5, 5)

L

PO 4 4

4 90 K (3, 1)

N (6, 3) M x 8

K

8

N

46. The move is a translation 15 feet out from the wall and 21 feet to the left, then a rotation of 90° clockwise. 47. Opposite sides of a parallelogram are congruent. Set the expressions for opposite sides equal and solve. y y2 0 y2 y 0 y(y 1) 0 y or 0 y 1 y0 y1 Since y represents a side length, which must be positive, y 1. 6x ¬4x 8 2x ¬8 x ¬4 So, when x is 4 and y is 1, the quadrilateral is a parallelogram. 48. Opposite sides of a parallelogram are congruent. Set the expressions for opposite sides equal and solve. 5y ¬2y 36 3y ¬36 y ¬12 6x 2 ¬64 6x ¬66 x ¬11 So, when x is 11 and y is 12, the quadrilateral is a parallelogram. 49. Opposite angles of a parallelogram are congruent and the sum of its interior angles is 360°. 2x 8 ¬120 2x ¬112 x ¬56 120 120 2(5y) ¬360 10y ¬120 y ¬12 So, when x is 56 and y is 12, the quadrilateral is a parallelogram.

Chapter 9

310

1 1 55. 1 2, 3, 4 Since the measure of the longest side 1 1 1 is 1 2 , 2 must be c, and a and b are 3 and 4 .

59.

a2 b2 ¬c2

y Q

R P

2

2 2 13 14 ¬12 1 1 1 1 6 ¬4 9 25 1 14 4 ¬4 25 1 Since 14 4 4, segments with these measures

x

S From Exercise 58, slope of P Q 1 slope of S R 1, slope of Q R 1, and slope of P S 1. Since the product of the slopes of adjacent sides of quadrilateral PQRS is 1, the adjacent sides are perpendicular.

cannot form a right triangle. Therefore, they do not form a Pythagorean triple. 56. By the Triangle Midsegment Theorem, B A E F and AB 1 C D F and BC 1 2 EF, B 2 DF,

60.

y Q

C D E and AC 1 and A 2 DE. So, EF 30,

DF 22, DE 26, and the perimeter is 30 22 26 78. 57. By the Triangle Midsegment Theorem,

R P

AB FC, AC 1 2 DE, and BC DA. So, AB 7,

x

BC 10, and AC 9. 58.

S

y Q

Use the distance formula to find the length of each side. d ¬ (x x1)2 (y2 y1)2 2 2 2 PQ ¬ (1 5) (6 2) 2 ¬ (4) 42 ¬ 32 QR ¬ (3 1)2 (2 6 )2 2 2 ¬ (4) (4 ) ¬ 32 RS ¬ [1 ( 3)]2 (2 2)2 2 ( ¬ 4 4)2 ¬ 32 2 ( PS ¬ (1 5) 2 2)2 2 2 ¬ (4) (4 ) ¬ 32 61. The measures of the sides of quadrilateral PQRS are equal. Opposite sides are parallel and adjacent sides are perpendicular. PQRS is a square. 62. Corresponding sides of similar polygons are proportional.

R P x

S Q P and R S are opposite sides. y y

2 1 Q ¬ slope of P x x 2

6 2 ¬ 15

1

4 ¬ 4

¬1

2 2

S ¬ slope of R 3) 1 ( 4 ¬ 4 ¬1 R Q and P S are opposite sides.

26 R ¬ slope of Q 3 1 4 ¬ 4

AB scale factor ¬ W X 8 ¬ 12

¬1

2 2 S ¬ slope of P 15 4 ¬ 4 ¬1 The opposite sides of quadrilateral PQRS have the same slopes. Therefore, the sides are parallel.

¬2 3

The scale factor is 2 3.

311

Chapter 9

AB 8 2 63. The scale factor is W X 1 2 3. The ratios of the measures of the corresponding sides of similar polygons are equal.

9-5

AB BC W X ¬ XY 2 10 ¬ X Y 3 3 XY ¬ 2 (10)

Dilations

Pages 493–494 Check for Understanding 1. Dilations only preserve length if the scale factor is 1 or 1. So for any other scale factor, length is not preserved and the dilation is not an isometry. 2. Sample answer:

XY ¬15 AB 8 2 64. The scale factor is W X 1 2 3. The ratios of the measures of the corresponding sides of similar polygons are equal.

B

A B

A

AB CD W X ¬ YZ 2 10 ¬ Y Z 3 (10) YZ ¬3 2

D

YZ ¬15

A

B

D

C C C

D

AB 8 2 65. The scale factor is W X 1 2 3. The ratios of the measures of the corresponding sides of similar polygons are equal.

3. Trey; Desiree found the image using a positive scale factor. 4. Since |4| 1, the dilation is an enlargement. , CW , CV , and CU . Since r is positive, Draw CX X, W, V, and U will lie on the continuation of the sides of the quadrilateral. Locate X, W, V, and U so that CX 4(CX), CW 4(CW), CV 4(CV), and CU 4(CU). Draw quadrilateral XWVU.

AB AD W X ¬ W Z 15 2 ¬ WZ 3 3 WZ ¬ 2 (15)

WZ ¬22.5

Page 489 Geometry Activity: Tessellations and Transformations 1. Yes; whatever space is taken out of the square is then added onto the outside of the square. The area does not change; only the shape changes. 2. Modify the bottom of the unit to be like the right side of the triangle. Erase the bottom and right original sides of the triangle.

C

5. Since 1 5 1, the dilation is a reduction. Draw , CR , CS , CT , CU , CV . Locate P, R, S, T, U, CP 1 and V so that CP 1 5 (CP), CR 5 (CR),

3.

1 1 CS 1 5 (CS), CT 5 (CT), CU 5 (CU), and CV 1 5 (CV). Draw hexagon PRSTUV.

R

4. P

S R S T P C V U

5.

V

T

U

Chapter 9

312

6. Since |2| 1, the dilation is an enlargement. Draw C E , C D , C G , and C F . Since r is negative, E, D, G, and F will lie on rays that are opposite to CE, CD, CG, and CF, respectively. Locate E, D, G, and F so that CE 2(CE), CD 2(CD), CG 2(CG), and CF 2(CF). Draw quadrilateral EDGF. E

10. Find K, L, and M using the scale factor, r 3. Preimage (x, y)

Image (3x, 3y)

K(5, 8)

K(15, 24)

L(3, 4)

L(9, 12)

M(1, 6)

M(3, 18)

D

24

L

y

K

12 K

L

F

24

12 12

G

24 x

12

M

M

C

24

G

F 11. For ease, compare diagonals of the figures. D

image length

scale factor ¬ preimage length

E

7. AB 3, r 4 Use the Dilation Theorem. AB |r|(AB) AB (4)(3) AB 12

8 un its r ¬ 4 units

r ¬2 Since the scale factor is greater than 1, the dilation is an enlargement. 12. Compare the vertical sides of the triangles.

8. AB 8, r 2 5 Use the Dilation Theorem. AB ¬|r|(AB)

image length

scale factor ¬ preimage length 4 un its r ¬ 6 units

8 ¬2 5 (AB)

r ¬2 3

20 ¬AB 9. Find P and Q using the scale factor, r 1 3. Preimage (x, y)

Image y x3,

P(9, 0)

P(3, 0)

Q(0, 6)

Q(0, 2)

Since 0 |r| 1, the dilation is a reduction. 13. C; The drawing and the garden are similar. 12 ft x 18 ft ¬ 8 in. x 2 ¬ 8 in. 3 5 1 3 in. ¬x

3

y


Q

14. Since |3| 1, the dilation is an enlargement. Draw CX, CY, and CZ. Since r is positive, X, Y, and Z will lie on the continuation of the sides of the triangle. Locate X, Y, and Z so that CX 3(CX), CY 3(CY), and CZ 3(CZ). Draw XYZ.

Q O

P

P x

X

X C Y

Y

313

Z

Z

Chapter 9

15. Since |2| 1, the dilation is an enlargement. Draw CT, CS, CR, and CP. Since r is positive, T, S, R, and P will lie on the continuations of the sides of the quadrilateral. Locate T, S, R, and P so that CT 2(CT), CS 2(CS), CR 2(CR), and CP 2(CP). Draw quadrilateral TSRP. T

18. Since |1| 1, the dilation is a congruence transformation. Draw CE, CD, CA, and CB. Since r is negative, E, D, A, and B will lie on rays that are opposite to CE, CD, CA, and CB. Locate E, D, A, and B so that CE CE, CD CD, CA CA, and CB CB. Draw quadrilateral EDAB.

S T C P

B

D B

R

E

A

CL , C M , and C N . Since r is positive, the reduction will have the same orientation. Locate K, L, M, and N so that CK 1 2 (CK),

19. Since 1 4 1, the dilation is a reduction. Draw L C , C M , and C N . Since r is negative, L, M, and , CM , and N lie on rays that are opposite to CL CN, respectively. Locate L, M, and N so that 1 1 CL 1 4 (CL), CM 4 (CM), and CN 4 (CN). Draw LMN.

1 1 CL 1 2 (CL), CM 2 (CM), and CN 2 (CN).

Draw quadrilateral KLMN. N N

K

M

C

L

M L

D

C

R

P

16. Since 21 1, the dilation is a reduction. Draw C K ,

K

A

E

S

M

N

C N

L 17. Since 2 5 1, the dilation is a reduction. Draw R C , C S , and C T . Since r is positive, the reduction will have the same orientation. Locate R, S, and 2 T so that CR 2 5 (CR), CS 5 (CS), and 2 CT 5(CT). Draw RST.

M

20. ST 6, r 1 Use the Dilation Theorem. ST |r|(ST) ST (1)(6) ST 6

R T

3 21. ST 4 5, r 4 Use the Dilation Theorem. ST |r|(ST)

R T

C S

4 ST 3 4 5

S

ST 3 5 22. ST 12, r 2 3 Use the Dilation Theorem. ST ¬|r|(ST) 12 ¬2 3 (ST)

18 ¬ST

1 2 3 23. ST 5 , r 5

Use the Dilation Theorem. ST ¬|r|(ST)

1 2 3 5 ¬ 5 (ST)

4 ¬ST

Chapter 9

314

L

24. ST 32, r 5 4

Find X, Y, and Z using the scale factor, r 1 2.

Use the Dilation Theorem. ST |r|(ST)

Preimage (x, y)

ST 5 4 (32)

ST 40 25. ST 2.25, r 0.4 Use the Dilation Theorem. ST |r|(ST) ST (0.4)(2.25) ST 0.9 26. Find F, G, and H using the scale factor, r 2. Preimage (x, y)

Image (2x, 2y)

F(3, 4)

F(6, 8)

G(6, 10)

G(12, 20)

H(3, 5)

H(6, 10)

12x, 12y

X(1, 2)

X1 2 , 1

Y(4, 3)

Y2, 3 2

Z(6, 1)

Z3, 1 2

y OX

x

Z

Z

Y X Y

Find F, G, and H using the scale factor, r 1 2.

28. Find P, Q, R, and S using the scale factor, r 2.

Image

Preimage (x, y)

Image

12x, 12y

Preimage (x, y)

Image (2x, 2y)

P(1, 2)

P(2, 4)

F(3, 4)

F3 2 , 2

Q(3, 3)

Q(6, 6)

G(6, 10)

G(3, 5)

R(3, 5)

R(6, 10)

H(3, 5)

5 H3 2, 2

S(1, 4)

S(2, 8)

20

y

Find P, Q, R, and S using the scale factor, r 1 2.

G

Preimage (x, y)

16 12

H

8

H

F G

4

F 4

O

4

8

Preimage (x, y)

Image (2x, 2y)

X(1, 2)

K(2, 4)

Y(4, 3)

Y(8, 6)

Z(6, 1)

12x, 12y

P(1, 2)

P1 2 , 1

Q(3, 3)

3 Q3 2, 2

R(3, 5)

5 R3 2, 2

S(1, 4)

S1 2 , 2

12 x

27. Find X, Y, and Z using the scale factor, r 2.

Image

y

R S Q P

Z(12, 2) S

R Q

P O

315

x

Chapter 9

29. Find K, L, M, and N using the scale factor, r 2. Preimage (x, y)

Image (2x, 2y)

K(4, 2)

K(8, 4)

L(4, 6)

L(8, 12)

M(6, 8)

M(12, 16)

N(6, 10)

N(12, 20)

33. Compare QT and QT. Use the Pythagorean Theorem to find the side lengths. image length scale factor ¬ preimage length

4 13 units 3 r ¬ 2

42 12 units

17 3

r ¬

17 1 r ¬ 3

Find K, L, M, and N using the scale factor, r 21. Preimage (x, y)

Image

K(4, 2)

K(2, 1)

L(4, 6)

L(2, 3)

M(6, 8)

M(3, 4)

N(6, 10)

N(3, 5)

L

Since 0 |r| 1, the dilation is a reduction. 34. Compare YZ and YZ. Note that the scale factor is negative since the image appears on the opposite side of the center with respect to the preimage. Use the Pythagorean Theorem to find the side lengths. image length scale factor ¬

12x, y

12

preimage length

3 1 4 units r ¬ 2

12

8

4

25

4 r ¬

25 1 r ¬4

M

K

4

Since 0 |r| 1, the dilation is a reduction. 35. Compare BD and BD. Note that the scale factor is negative since the image points appear on the opposite side of the center with respect to the preimage points. Use the Pythagorean Theorem to find the side lengths.

K O 4

4

8

12 x

N

8

M

image length preimage length

12

scale factor ¬

16

r ¬

42 12 units

1 2 2 2

20

N

2

units

17

r ¬ 17

2

30. Compare sides of the squares. image length scale factor ¬ preimage length 6 un its r ¬ 2 units

r ¬2 Since |r| 1, the dilation is an enlargement. 36. Determine the width in inches of the actual wingspan of the SR-71. 12 in. (55 ft) 1 ft 7 in. 660 in. 7 in. 667 in. Find the scale factor by dividing the wingspan of the model by the wingspan of the plane.

r ¬3 Since the scale factor is greater than 1, the dilation is an enlargement. 31. Compare the vertical sides of the triangles. image length preimage length 2 un its r ¬ 4 units r ¬1 2

scale factor ¬

1 14 1 66 7 66 7 4 8 14

1 The scale factor is about . 48

37. Each dimension is reduced by a factor of 0.75. 0.75(10) 7.5 0.75(14) 10.5 The new dimensions are 7.5 in. by 10.5 in.

Since 0 |r| 1, the dilation is a reduction. 32. By inspection, we see that the scale factor is 1. This is a congruence transformation.

Chapter 9

2

42 32 units

y

8

L

2

316

38. Find the ratio of the area of the image to that of the preimage.

44. The width and height of the photograph are increased by 150%, or a factor of 1.5. 1.5(480) 720 1.5(640) 960 The dimensions of the image are 960 pixels by 720 pixels. 45. The original width is 640 pixels. To reduce it to 32 pixels, Dinah must use a scale factor 3 2 1 of 640 20 .

area of image 0.75(10) 0.75(14) ¬ 10 14 area of preimage

¬0.752 ¬0.5625 9

¬ 16

9 The area of the image is 16 that of the preimage. 39. Each side of the rectangle is lengthened by a factor of 4, so the perimeter is four times the original perimeter. 40. Find the ratio of the areas.

46. The original height is 480 pixels. To enlarge it to 60 0 5 600 pixels, Dinah used a scale factor of 480 4 . 47. The dimensions of the photograph are 10 cm by 12 cm. The space available is 6 cm by 8 cm. 6 0.6 and 8 0.67, so a scale factor of 0.6 is 10 12 required for the photograph to be as large as possible on the page. So, she should save the image file at 60%. 48. Use the distance formula to find the length of each side. d (x2 x1)2 (y2 y1)2

area of image (4b)( 4h) bh area of preimage

16 The area is 16 times the original area. 41. Given: dilation with center C and scale factor r Prove: ED r(AB) C

A

E

2 (8 CD (3 7) 7)2 16 1 17 BC (7 5 )2 [7 (1 )]2 4 64 2 17 AB [5 ( 1)]2 (1 1)2 36 4 2 10 AD [3 ( 1)]2 (8 1)2 16 49 65 Find the perimeter. P ¬ 17 2 17 2 10 65 ¬26.8 The perimeter is about 26.8 units. 49. Find A, B, C, and D using the scale factor, r 2.

B D Proof: CE r(CA) and CD r(CB) by the definition of CE CD CE CD a dilation. CA r and CB r. So, CA CB by substitution. ACB ECD, since congruence of angles is reflexive. Therefore, by SAS Similarity, ACB is similar to ECD. The corresponding sides of similar triangles are ED CE CE proportional, so AB CA . We know that CA r, E D so AB r by substitution. Therefore, ED r(AB) by the Multiplication Property of Equality. 42. First dilation: (x, y) → (rx, ry) Second dilation: (rx, ry) → (r2x, r2y) Find r2 using the x-values of A and A. 3 r2(12) 1 r2 4

Preimage (x, y) Image (2x, 2y)

1 r 2

A(2, 2) B(10, 2) C(14, 14) D(6, 16)

A(1, 1) B(5, 1) C(7, 7) D(3, 8)

So, the scale factor is 1. 2

43. Use the distance formula to find XY and XY. d (x2 x1)2 (y2 y1)2 XY (0 4 )2 (5 2)2 16 9 5 XY (12 6)2 (11 3)2 36 64 10 Find the absolute value of the scale factor.

8

y D

C

4

B A 12

8

4

image length

4 B 8x

O

r preimage length

4

10 5 2 The absolute value of the scale factor is 2.

8

A

12 C D

317

16

Chapter 9

Dilation with scale factor of 1 3: y x (x, y) → 3, 3

50. Use the distance formula to find the length of each side. dz (x x1)2 (y2 y1)2 2

1 0 4 (10, 4) → T 3 , 3 7 (7, 7) → U 7 3, 3 (3, 1) → V 1, 1 3

(10 2)2 [2 (2)]2

AB 144 16 4 10 2 BC [14 (10)] (14 2)2 16 256 4 17 2 [ CD [6 (14)] 16 (14 )]2 64 4 2 17 AD (6 2)2 [16 (2 )]2 64 196 2 65 Find the perimeter. P ¬4 10 4 17 2 17 2 65 ¬53.5 The perimeter of quadrilateral ABCD is about 53.5 units, so it is twice the perimeter of quadrilateral ABCD. 51. T(6, 5), U(3, 8), V(1, 2) Reflection in the x-axis: (x, y) → (x, y) T(6, 5) → (6, 5) U(3, 8) → (3, 8) V(1, 2) → (1, 2)

y

U V

T

x

52. Translate the points so that the center is the origin. (x, y) → (x 3, y 5) G(3, 5) → (0, 0) H(7, 4) → (4, 9) I(1, 0) → (4, 5)

y

y 12 8

G 4

x

I V

12 8

T

4

x 4

4

8

12

H

8 12

U Translation with (x, y) → (x 4, y 1): (6, 5) → (10, 4) (3, 8) → (7, 7) (1, 2) → (3, 1)

16 20

Dilate the figure using the scale factor 2. (x, y) → (2x, 2y) (0, 0) → (0, 0) (4, 9) → (8, 18) (4, 5) → (8, 10)

y

x

Chapter 9

318

55. A; find the slope of 3x 5y 12. 3x 5y¬ 12 5y¬ 3x 12 1 2 y¬ 3 5x 5

y 12 8

4

The slope is 3 5. The slopes of perpendicular lines are opposite reciprocals of each other. 1 5 3 3

8

The slope is 5 3.

4 x 12 8

4

4

8

12

5

12

Page 497

16 20

Translate the points back so that the center is at (3, 5). (x, y) → (x 3, x 5) (0, 0) → G(3, 5) (8, 18) → H(11, 13) (8, 10) → I(5, 5) y 12 8

G 4 x 12 8

4

I

4

8

12

4 8

12 16


56. No; use the algebraic method to determine whether a semi-regular tessellation can be created using equilateral triangles and regular pentagons of side length 1 unit. Each interior angle of an equilateral triangle measures 60°, and each interior angle of a regular 180(5 2) pentagon measures or 108°. 5 Find whole number values for h and t so that 60h 108t 360. Let h 1. 60(1) 108t¬ 360 60 108t¬ 360 108t¬ 300 t¬ 2.8 Let h 2. 60(2) 108t¬ 360 120 108t¬ 360 108t¬ 240 t¬ 2.2 Let h 3. 60(3) 108t¬ 360 180 108t¬ 360 108t¬ 180 t¬ 1.7 Let h 4. 60(4) 108t¬ 360 240 108t¬ 120 108t¬ 120 t¬ 1.1 Let h 5. 60(5) 108t¬ 360 300 108t¬ 360 108t¬ 60 t¬ 0.6 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from equilateral triangles and regular pentagons. 57. No; use the algebraic method to determine whether a semi-regular tessellation can be created using regular octagons and hexagons of side length 1 unit. Each interior angle of a regular octagon measures 180(8 2) or 135°, and each interior angle of a 8 180(6 2) regular hexagon measures or 120°. 6

H

20

The coordinates of the vertices of the image are G(3, 5), H(11, 13) and I(5, 5). 53. Sample answer: Yes; a cut and paste produces an image congruent to the original. Answers should include the following. • Congruent figures are similar, so cutting and pasting is a similarity transformation. • If you scale both horizontally and vertically by the same factor, you are creating a dilation. 54. B; the pentagons are similar. Find the scale factor by dividing the length of the radius of the larger pentagon by that of the smaller pentagon. 6 6 Scale factor 6 1 2 6 2 So, the perimeter of the larger pentagon is twice that of the smaller pentagon (5n). The perimeter of the larger pentagon is 10n.

319

Chapter 9

60. First graph ABC and point P. Draw a segment from point P to point A. Use a protractor to measure a 90° angle counterclockwise with P A as one side. Draw PR. Use a compass to copy P A . Name the segment P onto PR A . Repeat with points B and C. ABC is the image of ABC under a 90° counterclockwise rotation about point P.

Find whole number values for h and t so that 135h 120t 360. Let t 1. 135h 120(1)¬ 360 135h 120¬ 360 135h¬ 240 t¬ 1.8 Let t 2. 135h 120(2)¬ 360 135h 240¬ 360 135h¬¬120 t¬ 0.9 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from regular octagons and hexagons. 58. Yes; use the algebraic method to determine whether a semi-regular tessellation can be created using squares and equilateral triangles of side length 1 unit. Each interior angle of a square measures 90°, and each interior angle of a triangle measures 60°. Find whole number values for h and t so that 90h 60t 360. Let h 2. 90(2) 60t 360 180 60t 360 60t 180 t3 When h 2 and t 3, there are two squares with three triangles at each vertex.

B C C 90

P

x

B

O

A 61. First graph parallelogram DEFG and point P. Draw a segment from point P to point D. Use a protractor to measure a 90° angle clockwise with D P as one side. Draw PR. Use a compass to copy D P onto PR. Name the segment P D . Repeat with points E, F, and G. Parallelogram DEFG is the image of DEFG under a 90° clockwise rotation about point P.

60 60

A

y

y

E

60

90 90

F x

O

59. No; use the algebraic method to determine whether a semi-regular tessellation can be created using regular hexagons and dodecagons of side length 1 unit. Each interior angle of a regular hexagon 180(6 2) measures or 120°, and each interior 6 180(12 2) angle of a regular dodecagon measures 12 or 150°. Find whole number values for h and t so that 120h 150t 360. Let h 1. 120(1) 150t¬ 360 120 150t¬ 360 150t¬ 240 t¬ 1.6 Let h 2. 120(2) 150t¬ 360 240 150t¬ 360 150t¬ 120 t¬ 0.8 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from regular hexagons and dodecagons.

Chapter 9

D 90

D

G E

P

G

F

62. Yes; the opposite sides of a rectangle are congruent, and the diagonals are congruent. 63. Given: J L B is the midpoint of J L . Prove: JHB LCB J C

B

H

L Proof: It is known that J L. Since B is the midpoint of J L , J B L B by the Midpoint Theorem. JBH LBC because vertical angles are congruent. Thus, JHB LCB by ASA.

320

5. Find A, B, and C using the scale factor, r 1 2.

64. Use the tangent ratio. B C tan A AC

A(10, 2) B(1, 6)

B(1 2 , 3)

C(4, 4)

C(2, 2)

A tan1 2 3

Use a calculator to find mA. mA 33.7 65. Use the tangent ratio. BC tan A AB

8

C

2 8 tan A 7

y

Image x 2, 2 A(5, 1)

Preimage (x, y)

2 tan A 3

y

B

4

tan1 4

A Use a calculator to find mA. mA 76.0 66. Use the cosine ratio.

A O

A

4

8

x

C

B

AC cos A AB 20 cos A 32

A cos1 5 8

9-6

Use a calculator to find mA. mA 51.3

Page 497

Page 501 Geometry Activity: Comparing Magnitude and Components of Vectors

Practice Quiz 2

1. See students’ work. 2. The components of b are twice the components of a . 3. The components of b are three times the components of a . 4. Sample answer: The magnitude is n times greater than the magnitude of x, y, and the direction is the same.

1. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is semi-regular because it is composed of more than one type of regular polygon. 2. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles.

Pages 502–503 Check for Understanding 1. Sample answer: 7, 7 y

3. Since 3 4 1, the dilation is a reduction. D , C F , and C E . Locate D, F, and E on Draw C D C , C F , and C E so that CD 3 4 (CD), (CF), and CE 3(CE). Draw DFE. CF 3 4 4

D C E

E

4, 4

3, 3

O

x

2. Two equal vectors must have the same magnitude and direction, but parallel vectors have the same direction. The magnitude of parallel vectors can be different. 3. Sample answer: Using a vector to translate a figure is the same as using an ordered pair because a vector has horizontal and vertical components which can be represented by ordered pairs. 4. Find the change in x-values and the corresponding change in y-values. AB x2 x1, y2 y1 1 (4), 3 (3) 5, 6

D

F

Vectors

F

4. Since 2 1, the dilation is an enlargement. Since r is negative, P, R, S, T, and U will lie on rays that are opposite to CP, CR, CS, CT, and CU respectively. Locate P, R, S, T, and U so that CP 2(CP), CR 2(CR), CS, 2(CS), CT 2(CT), and CU 2(CU). Draw PRSTU. R P T U S S C R P U T

321

Chapter 9

y y

2 1 tan A x x

5. Find the change in x-values and the corresponding change in y-values. CD x2 x1, y2 y1 0 (4), 1 4 4, 3 6. Find the magnitude using the distance formula.

2

1

4 0 12 (6) 2 3 mA tan1 2 3

33.7 A vector in standard position that is equal to AB forms a 33.7° angle with the negative x-axis in the third quadrant. So it forms a 180 33.7 or 213.7° angle with the positive x-axis. Thus, AB has a magnitude of 2 13 or about 7.2 units and a direction of about 213.7°. 8. Find the magnitude using the Pythagorean Theorem. v x2 y2 82 (15) 2 17 Vector v lies in the fourth quadrant. Find the direction.

AB ¬ (x x1)2 (y2 y1)2 2 ¬ (3 2)2 (3 7 )2 ¬ 41 ¬6.4 Graph AB to determine how to find the direction. Draw a right triangle that has AB as its hypotenuse and an acute angle at A. y

A

B

y

tan x

x

15 8 1 5 m tan1 8

y y

2 1 tan A x x 2

1

61.9 v forms a 61.9° angle with the positive x-axis in the fourth quadrant. So, it forms a 360 61.9 or 298.1° angle with the positive x-axis. Thus, v has a magnitude of 17 units and a direction of about 298.1°. 9. First, graph JKL. Next, translate each vertex by t , 1 unit left and 9 units up. Connect the vertices to form JKL.

3 7 3 2

4 5 mA tan1 4 5 38.7 A vector in standard position that is equal to AB forms a 38.7° angle with the negative x-axis in the third quadrant. So it forms a 180 38.7 or 218.7° angle with the positive x-axis. Thus, AB has a magnitude of 41 or about 6.4 units and a direction of about 218.7°. 7. Find the magnitude using the distance formula. AB (x x1)2 (y2 y1)2 2

L

12

L

2 ( [12 (6)] 4 0)2 2 13 7.2 Graph AB to determine how to find the direction. Draw a right triangle that has AB as its hypotenuse and an acute angle at A.

K

J

8 4 O

8

4

J

K

4

x

10. First, graph trapezoid PQRS. Next, translate each vertex by u, 3 units right and 3 units down. Connect the vertices to form trapezoid PQRS.

y

4

A(6, 0)

y

4

B

322

Q

P

O S

x

Chapter 9

y

16

Q

P

8

R 12

16

x

R S

11. First, graph WXYZ. Next, translate each vertex by e , 1 unit left and 6 units up. Finally, translate each vertex by f , 8 units right and 5 units down. Connect the vertices to form WXYZ.

can be found by adding the two vectors. Find the components of the current vector. x, y 3cos(30°), 3sin(30°) 3 3

, 3

y

Y

4

Y

8

4

8

12

x

X

X

(10 1.5 ) (1.5 3 )2 12.7 The resultant vector lies in the fourth quadrant. Find the direction. 2

12. Find the resultant vector. g h 4 0, 0 6 4, 6 Find the magnitude to the resultant vector. g h x2 y2 42 62 2 13 7.2 The resultant vector lies in the first quadrant. Find the direction. y tan x

y

tan x 1 .5 10 1.5 3 1.5 m tan1 10 1.5 3 6.8 The speed of the boat is about 12.7 knots, at a direction of about 6.8° south of due east.

6 4 3 2

Use the Pythagorean Theorem to find the magnitude. 10 1.5 3, 1.5

W W

2

Z 4 Z O

2

Find the resultant vector. 3 3

3 10 , 1.5 2 , 0 2 10 1.5 3

Pages 503–505 Practice and Apply 15. Find the change in x-values and the corresponding change in y-values. AB x2 x1, y2 y1 3 1, 3 (3) 2, 6 16. Find the change in x-values and the corresponding change in y-values. CD x2 x1, y2 y1 3 (2), 4 0 1, 4 17. Find the change in x-values and the corresponding change in y-values. EF x2 x1, y2 y1 3 4, 1 3 7, 4 18. Find the change in x-values and the corresponding change in y-values. GH x2 x1, y2 y1 2 (3), 4 4 5, 0 19. Find the change in x-values and the corresponding change in y-values. LM x2 x1, y2 y1 1 4, 3 (2) 3, 5 20. Find the change in x-values and the corresponding change in y-values. NP x2 x1, y2 y1 1 (4), 1 (3) 3, 2 21. Find the magnitude using the distance formula. CD (x x1)2 (y2 y1)2 2

m tan1 56.3 The resultant vector forms a 56.3° angle with the positive x-axis in the first quadrant. Thus, g h has a magnitude of 2 13 or about 7.2 units and a direction of about 56.3°. 13. Find the resultant vector. t u 0 12, 9 9 12, 18 Find the magnitude of the resultant vector. t u x2 y2 122 (18 )2 6 13 21.6 The resultant vector lies in the fourth quadrant. Find the direction. y tan x 3 2

8 1 12 3 2

m tan1 3 2 56.3 The resultant vector forms a 56.3° angle with the positive x-axis in the fourth quadrant. So, it forms a 360 56.3 or 303.7° angle with the positive x-axis. Thus, t u has a magnitude of 6 13 or about 21.6 units and a direction of about 303.7°. 14. The initial path of the boat is due east, so a vector representing the speed of the boat lies on the positive x-axis and is 10 units long. The current is flowing 30° south of east, so a vector representing the speed of the current will be 30° below the positive x-axis 3 units long. The resultant speed

(9 4 )2 (2 2)2 5

323

Chapter 9

Thus, CD has a magnitude of 2 5 or about 4.5 units and a direction of 296.6°. 24. Find the magnitude using the distance formula.

Since CD 5, 0, it is along the positive x-axis. Thus, CD has a magnitude of 5 units and a direction of 0°. 22. Find the magnitude using the distance formula. CD (x x1)2 (y2 y1)2 2

CD (x2 x1)2 (y2 y1)2

(2 0)2 [4 (7)]2 13 3.6 Graph CD to determine how to find the direction. Draw a right triangle that has CD as its hypotenuse and an acute angle at C.

2

[2 (2)] (5 1)2

4 2 5.7 Graph CD to determine how to find the direction. Draw a right triangle that has CD as its hypotenuse and an acute angle at C.

y x

y

D(2, 5)

D C

C

x

y y

2 1 tan C ¬ x x

y2 y1 tan C ¬ x2 x1

2

1

4 (7) ¬ 2 0

5 1 ¬ 2 ( 2) ¬1 mC tan1 1 45 A vector in standard position that is equal to CD forms a 45° angle with the positive x-axis in the first quadrant. Thus, CD has a magnitude of 4 2 or about 5.7 units and a direction of 45°. 23. Find the magnitude using the distance formula. CD (x x1)2 (y2 y1)2 2

¬ 1.5 mC tan1 (1.5) 56.3 A vector in standard position that is equal to CD forms a 56.3° angle with the negative x-axis in the second quadrant. So it forms a 180 56.3 or 123.7° angle with the positive x-axis. Thus, CD has a magnitude of 13 or about 3.6 units and a direction of 123.7°. 25. Find the magnitude using the distance formula. CD (x x1)2 (y2 y1)2 2 [6 ( 8)]2 [0 (7)]2 7 5 15.7 Graph CD to determine how to find the direction. Draw a right triangle that has CD as its hypotenuse and an acute angle at C.

[3 (5)]2 (6 10)2 2 5 4.5 Graph CD to determine how to find the direction. Draw a right triangle that has CD as its hypotenuse and an acute angle at C. C

y

y

D

x

D C

x

y y

2 1 tan C ¬ x x

y2 y1 tan C ¬ x2 x1

2

6 10 ¬ 3 (5) ¬2 mC tan1 (2) 63.4 A vector in standard position that is equal to CD forms a 63.4° angle with the positive x-axis in the fourth quadrant. So it forms a 360 63.4 or 296.6° angle with the positive x-axis.

Chapter 9

1

0 (7) ¬ 6 (8)

¬0.5 mC tan1 (0.5) 26.6 A vector in standard position that is equal to CD forms a 26.6° angle with the positive x-axis in the first quadrant. Thus, CD has a magnitude of 7 5 or about 15.7 units and a direction of 26.6°.

324

y

tan θ x

26. Find the magnitude using the distance formula. CD (x x1)2 (y2 y1)2 2

15 1 2

(2 10)2 [2 (3)]2

145 12.0 Graph CD to determine how to find the direction. Draw a right triangle that has CD as its hypotenuse and an acute angle at C.

5 4

mθ tan1 5 4 51.3 u forms a 51.3° angle with the negative x-axis in the second quadrant. So, it forms a 180 51.3 or 128.7° angle with the positive x-axis. Thus, u has a magnitude of 3 41 or about 19.2 units and a direction of about 128.7°. 29. Find the magnitude using the Pythagorean Theorem. v x2 y2 (25) 220) (2 5 41 32.0 Vector v lies in the third quadrant. Find the direction.

y x

D C

y y

2 1 tan C ¬ x x 2

1

y

2 (3) ¬ 2 10 1 ¬ 12 1 mC tan1 12

tan θ x 2 0 25

4 5

mθ tan1 4 5 38.7 v forms a 38.7° angle with the negative x-axis in the third quadrant. So, it forms a 180 38.7 or 218.7° angle with the positive x-axis. Thus, v has a magnitude of 5 41 or about 32.0 units and a direction of about 218.7°. 30. Find the magnitude using the Pythagorean Theorem. 2 y2 w x 2 36 (15)2 39 Vector w lies in the fourth quadrant. Find the direction.

4.8 A vector in standard position that is equal to CD forms a 4.8° angle with the negative x-axis in the second quadrant. So it forms a 180 4.8 or 175.2° angle with the positive x-axis. Thus, CD has a magnitude of 145 or about 12.0 units and a direction of 175.2°. 27. Find the magnitude using the Pythagorean Theorem. t x2 y2 72 24 2 25 Vector t lies in the first quadrant. Find the direction. y

tan θ x

y

tan θ x

24 7

5 1 36

24 mθ tan1 7

5 12

73.7 v forms a 73.7° angle with the positive x-axis in the first quadrant. Thus, v has a magnitude of 25 units and a direction of about 73.7°. 28. Find the magnitude using the Pythagorean Theorem. 2 y2 u x (12) 2 152 3 41 19.2 Vector u lies in the second quadrant. Find the direction.

5 mθ tan1 1 2 22.6 w forms a 22.6° angle with the positive x-axis in the fourth quadrant. So, it forms a 360 22.6 or 337.4° angle with the positive x-axis. Thus, w has a magnitude of 39 units and a direction of about 337.4°. 31. Find the magnitude using the Distance Formula. MN (x x1)2 (y2 y1)2 2 2 (9 [9 (3)] 3)2 6 2 8.5 Graph MN to determine how to find the direction. Draw a right triangle that has MN as its hypotenuse and an acute angle at M.

325

Chapter 9

N

Graph MN to determine how to find the direction. Draw a right triangle that has MN as its hypotenuse and an acute angle at M.

y

y

M

M x

x

N y y

2 1 tan M ¬ x x 2

1

9 3 ¬ 9 (3)

y y

2 1 tan M ¬ x x

¬1

2

1

2 2 ¬ 12 0

mM tan1 (1) 45 A vector in standard position that is equal to MN forms a 45° angle with the negative x-axis in the second quadrant. So it forms a 180 45 or 135° angle with the positive x-axis. has a magnitude of 6 2 Thus, MN or about 8.5 units and a direction of 135.0°. 32. Find the magnitude using the Distance Formula. MN (x x1)2 (y2 y1)2 2

¬1 3

mM tan1 1 3 18.4 A vector in standard position that is equal to MN forms an 18.4° angle with the negative x-axis in the third quadrant. So it forms a 180 18.4 or 198.4° angle with the positive x-axis. Thus, MN has a magnitude of 4 10 or about 12.6 units and a direction of 198.4°. 34. Find the magnitude using the Distance Formula. MN (x x1)2 (y2 y1)2 2

(2 8 )2 (5 1)2 2 13 7.2 Graph MN to determine how to find the direction. Draw a right triangle that has MN as its hypotenuse and an acute angle at M.

2 [6 1)] ( (8 7)2 274 16.6 Graph MN to determine how to find the direction. Draw a right triangle that has MN as its hypotenuse and an acute angle at M.

y

N

y

M M

x

x

y y

2 1 tan M ¬ x x 2

N

1

51 ¬ 2 8 2 ¬3

y y

2 1 tan M ¬ x x 2

mM tan1 2 3

33.7 A vector in standard position that is equal to MN forms a 33.7° angle with the negative x-axis in the second quadrant. So it forms a 180 33.7 or 146.3° angle with the positive x-axis. Thus, MN has a magnitude of 2 13 or about 7.2 units and a direction of 146.3°. 33. Find the magnitude using the Distance Formula. MN (x x1)2 (y2 y1)2 2

1 5 ¬ 7

1 5 mM tan1 7

65.0 A vector in standard position that is equal to MN forms an 65.0° angle with the positive x-axis in the fourth quadrant. So it forms a 360 65.0 or 295.0° angle with the positive x-axis. Thus, MN has a magnitude of 274 or about 16.6 units and a direction of 295.0°.

(12 0)2 (2 2)2 4 10 12.6

Chapter 9

1

8 7 ¬ 6 (1)

326

37. First, graph ABC. Next, translate each vertex by a , 6 units down. Connect the vertices to form ABC.

35. Find the magnitude using the Distance Formula. MN (x x1)2 (y2 y1)2 2 2 2 [1 1)] ( (1) 102 2 122 22.1 Graph MN to determine how to find the direction. Draw a right triangle that has MN as its hypotenuse and an acute angle at M.

y A 4 O

4

B

8

12

12

x

4

8x

4

4

C

y

M

A

C 8

B

38. First, graph DEF. Next, translate each vertex by b, 3 units left and 9 units down. Connect the vertices to form DEF.

N

y

D

y2 y1 tan M ¬ x2 x1

E

4

12 10 ¬ 1 (1)

12

¬11 mM tan1 (11) 84.8 A vector in standard position that is equal to MN forms an 84.8° angle with the positive x-axis in the fourth quadrant. So it forms a 360 84.8 or 275.2° angle with the positive x-axis.3 Thus, MN has a magnitude of 2 122 or about 22.1 units and a direction of 275.2°. 36. Find the magnitude using the Distance Formula. MN (x x1)2 (y2 y1)2 2

8

O

4

E F

4

D

x

4

8 12

F

39. First, graph square GHIJ. Next, translate each vertex by c , 3 units right and 8 units down. Connect the vertices to form square GHIJ. J I

[6 (4)]2 ( 4 0)2 2 5 4.5 Graph MN to determine how to find the direction. Draw a right triangle that has MN as its hypotenuse and an acute angle at M.

12

4

G 8

4

y O x

J

H

4

I

8

G

H 40. First, graph quadrilateral KLMN. Next, translate each vertex by x, 10 units left and 2 units up. Connect the vertices to form quadrilateral KLMN.

y

M x

y

K L N

N

N

8

K L

4

y y

12

2 1 tan M ¬ x x 2

1

8

M

4

O

4 x

M

4 0 ¬ 6 (4) ¬2 mM tan1 (2) 63.4 A vector in standard position that is equal to MN forms a 63.4° angle with the negative x-axis in the third quadrant. So it forms a 180 63.4 or 243.4° angle with the positive x-axis. Thus, MN has a magnitude of 2 5 or about 4.5 units and a direction of 243.4°.

327

Chapter 9

41. First, graph pentagon OPQRS. Next, translate each vertex by y, 5 units left and 11 units up. Connect the vertices to form pentagon OPQRS. y S O 12 K 8

Q

45. First, graph quadrilateral EFGH. Next, translate each vertex by p, 6 units left and 10 units up. Finally, translate each vertex by q, 1 unit right and 8 units down. Connect the vertices to form quadrilateral EFGH. G 16 y

P S

4

12

F F

8

O

R 8

O

4

4

x

4

P

4

E

Q

V W

T

X

6

12

24

V

U

O T

6

6

6

W

20

x

16

X

Y

O

A

4 O

A

D D

B

C

B

C 12 44. First, graph XYZ. Next, translate each vertex by p, 2 units right and 2 units up. Finally, translate each vertex by q, 4 units left and 7 units down. Connect the vertices to form XYZ. y Y

8

12

x

Z

4

X Z

8

X

Chapter 9

x

U V

S

W

T

U V

S

W 4

8

12

x

1 2 mθ tan1 5 67.4 The resultant vector forms a 67.4° angle with the positive x-axis in the first quadrant. Thus, a b has a magnitude of 13 units and a direction of about 67.4°. 48. Find the resultant vector. c d 0 (8), 8 0 8, 8 Find the magnitude of the resultant vector. c d x2 y2 (8)2 (8)2 8 2 11.3

Y 4

T

1 2 5

4

O

H

47. Find the resultant vector. a b 5 0, 0 12 5, 12 Find the magnitude of the resultant vector. a b x2 y2 52 1 22 13 The resultant vector lies in the first quadrant. Find the direction. y tan θ x

8x

4

y

8

y 4

4

12

43. First, graph ABCD. Next, translate each vertex by p, 11 units right and 6 units up. Finally, translate each vertex by q, 9 units left and 3 units down. Connect the vertices to form ABCD.

8

O

4

46. First, graph pentagon STUVW. Next, translate each vertex by p, 4 units left and 5 units up. Finally, translate each vertex by q, 12 units right and 11 units up. Connect the vertices to form pentagon STUVW.

12

Y

8

E

y

18

H

12

42. First, graph hexagon TUVWXY. Next, translate each vertex by z , 18 units left and 12 units up. Connect the vertices to form hexagon TUVWXY. U

G

328

The resultant vector lies in the first quadrant. Find the direction. y tan θ x

The resultant vector lies in the third quadrant. Find the direction. y tan θ x

8 8 1 mθ tan1 (1) 45 The resultant vector forms a 45° angle with the negative x-axis in the third quadrant. So it forms a 180 45 or 225° angle with the positive x-axis. Thus, c d has a magnitude of 8 2 or about 11.3 units and a direction of 225°. 49. Find the resultant vector. e f 4 7, 0 (4) 3, 4 Find the magnitude of the resultant vector. e f x2 y2 32 ( 4)2 5 The resultant vector lies in the fourth quadrant. Find the direction. y tan θ x

2 4 1 2

mθ tan1 1 2 26.6 The resultant vector forms a 26.6° angle with the positive x-axis in the first quadrant. Thus, w x has a magnitude of 2 5 or about 4.5 units and a direction of about 26.6°. 52. Find the resultant vector. y z 9 (10), 10 (2) 1, 12 Find the magnitude of the resultant vector. y z x2 y2 (1)2 (1 2)2 145 12.0 The resultant vector lies in the third quadrant. Find the direction. y tan θ x

4 3 mθ tan1 4 3 53.1 The resultant vector forms a 53.1° angle with the positive x-axis in the fourth quadrant. So it forms a 360 53.1 or 306.9° angle with the positive x-axis. Thus, e f has a magnitude of 5 units and a direction of about 306.9°. 50. Find the resultant vector. u v 12 0, 6 6 12, 12 Find the magnitude of the resultant vector. u v x2 y2 122 122 12 2 17.0 The resultant vector lies in the first quadrant. Find the direction. y tan θ x

1 2 1

12 mθ tan1 (12) 85.2 The resultant vector forms an 85.2° angle with the negative x-axis in the third quadrant. So it forms a 180 85.2 or 265.2° angle with the positive x-axis. Thus, y z has a magnitude of 145 or about 12.0 units and a direction of about 265.2°. 53. The first path of the freighter is due east, so a vector representing the path lies on the positive x-axis and is 35 units long. The second path of the freighter is due south, so a vector representing this path begins at the tip of the first vector and stretches 28 units in the negative y-direction. Add the two vectors, 35, 0 and 0, 28. 35 0, 0 (28) 35, 28 Use the Pythagorean Theorem to find the magnitude. 35, 28 352 (28 )2 44.8 The resultant vector lies in the fourth quadrant. Find the direction. y tan θ x

12 12 1 mθ tan1 (1) 45 The resultant vector forms a 45° angle with the positive x-axis in the first quadrant. Thus, u v has a magnitude of 12 2 or about 17.0 units and a direction of 45°. 51. Find the resultant vector. w x 5 (1), 6 (4) 4, 2 Find the magnitude of the resultant vector. w x x2 y2 2 22 4 2 5 4.5

8 2 35 4 5

mθ tan1 4 5

38.7 The distance the freighter traveled is about 44.8 mi, at a direction of about 38.7° south of due east.

329

Chapter 9

54. Let the initial direction of the swimmer be the positive x-direction, and the direction that the current flows by the positive y-direction. The speed and direction of the swimmer can be represented by the vector 4.5, 0, and those of the current can be represented by the vector 0, 2. Add the vectors. 4.5 0, 0 2 4.5, 2 Use the Pythagorean Theorem to find the magnitude. 4.5, 2 4.52 22 4.9 The resultant vector lies in the first quadrant. Find the direction. y tan θ x

59. Sample answer: Quantities such as velocity are vectors. The velocity of the wind and the velocity of the plane together factor into the overall flight plan. Answers should include the following. • A wind from the west would add to the velocity contributed by the plane resulting in an overall velocity with a larger magnitude. • When traveling east, the prevailing winds add to the velocity of the plane. When traveling west, they detract from it. 60. B; find the sum of the vectors. r q 5, 10 3, 5 8, 15 Use the Pythagorean Theorem to find the magnitude of the vector sum. q r 82 1 52 17 The magnitude is 17. 61. D; 5b 125 5b 53 So, b 3. 4b 3 43 3 64 3 192

2 4.5 4 9

mθ tan1 4 9

24 The swimmer is traveling about 4.9 mph at an angle of 24°. 55. Add the vectors representing the velocities of the wind and jet. 100, 0 450, 450 100 450, 0 450 350, 450 The resultant vector for the jet is 350, 450 mph. 56. From Exercise 55, the resultant vector is 350, 450. Use the Pythagorean Theorem to find the magnitude. 350, 450 (350 )2 4 502 570.1 The magnitude of the resultant is about 570.1 mph. 57. From Exercise 55, the resultant vector is 350, 450. Find the direction. y tan θ x

Page 505 Maintain Your Skills 62. AB 8, r 2 Use the Dilation Theorem. AB r(AB) AB (2)(8) AB 16 63. AB 12, r 1 2 Use the Dilation Theorem. AB r(AB) AB 1 2 (12)

AB 6

64. AB 15, r 3 Use the Dilation Theorem. AB r(AB) 15 (3)(AB) 5 AB 65. AB 12, r 1 4

450 3 50 9 7

mθ tan1 9 7

52.1 The direction of the resultant is about 52.1° north of due west. 58. Sample answer: Let one vector be 1, 0. Then the x-components of the other two vectors must sum to 1, the y-components must cancel, and the magnitudes of the other two vectors must be 1. Try 1 2 for the x-components. Find the y-components.

Use the Dilation Theorem. AB r(AB) 12 1 4 (AB)

48 AB 66. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is also semi-regular since more than one regular polygon is used.

y 1 2

1 ¬

2

2

2 1 ¬1 4 y 3 ¬y2 4

3

2 ¬y

Three vectors with equal magnitude, the sum of 3

, and which is 0, 0, are 1, 0, 1,

12, 23 . Chapter 9

2

2

330

67. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. 68. The opposite angles of the rhombus are congruent. WZY WXY and XYZ XWZ. mXYZ mXWZ mWZY mWXY ¬360 2mXYZ 2mWZY ¬360 2mXYZ 21 5 mXYZ ¬360

74.

2 7

2 2 8 8 8 1 1 1 2 5

8 2 8 2 8 2 7 1 2 1 5 1 10 6 10 6 1 4

99 51 15 3(9) 3(9)

mXYZ ¬150 69. The measures of all sides of the rhombus are equal. So, WX YZ 12. 70. mXYZ ¬5mWZY 150 ¬5mWZY 30 ¬mWZY mXZY ¬1 2 mWZY

77.

78. 30

The diagonals bisect each other perpendicularly. They also bisect the interior angles. The lengths of the diagonals are 2x and 2y. 2x 2(30 cos 25°) 54.4 2y 2(30 sin 25°) 25.4 To the nearest tenth, the lengths of the diagonals are 25.4 cm and 54.4 cm.

4 3 10 4

1(0) 2 1(6) 2

1(2) 2 1(0) 2

0 1 3 0

2(8) 2(4) 42 42 2(3) 2(7)

8 16 42 42 6 14

42166

12 4

4 8 2 14

4 12

11 11 22 3 4

(1)(2) 1(2) 1(2) 1(2)

22 22

44 11

9-7

1(3) (1)(4) 1(3) 1(4)

3 4 34

Transformations with Matrices

Pages 508–509 Check for Understanding 1. A(3, 3) A(3, 3) B(4, 1) and B(1, 4) imply (x, y) → (y, x). C(1, 1) and C(1, 1) imply (x, y) → (y, x). (x, y) → (y, x) occurs with reflection in the line y x. 0 1 The reflection matrix is . 1 0

5 1 8 5 1 5 8 2 7 6 3 7 2 6

22 2.52

y

30

1(4) 1(5) 2 2 1(4) 1(4) 2 2

42 42 238 74

25

5 3

¬15 71. The opposite angles of the rhombus are congruent. WXY WZY mWXY mWZY mWXY 30 (From Exercise 70, mWZY 30.) 72. 30

73.

15 3 27 27 3 15

4 5 0 2 76. 1 2 4 4 6 0

¬1 2 (30)

x

3(5) 3(1) 3(1) 3(5)

75. 3

12 5 mXYZ ¬360

30

2. Sample answer: The format used to represent the transformation is different in each method, but the result is the same. Positive values move a figure up or right, and negative values move a figure down or left.

331

Chapter 9

3. Sample answer:

2 1

2 2 2 1 1 1

4. The vertex matrix for ABC is The translation matrix is

9. The reflection matrix for a reflection in the y-axis is

3 5 4 1

0 . 2

3 7 . 54 1 1 6 3

2 2 2 . 1 1 1

Multiply the vertex matrix for HIJK by the reflection matrix to find the vertex matrix of the image. 5 1 3 7 1 0 5 1 3 7 4 1 6 3 0 1 4 1 6 3

The coordinates of the vertices of ABC are A(3, 3), B(1, 2), and C(2, 1). 5. The vertex matrix for rectangle DEFG is

13

The translation matrix is

06

0 0 0 . 6 6 6

The coordinates of the vertices of the image are

D 1 4 , 1 .

1 0 . 0 1

24

Chapter 9

63

6 2 . 7 7

5 . 1 Multiply the vertex matrix for E F by the reflection matrix to find the vertex matrix of the image. 1 0 2 5 2 5 0 1 4 1 4 1 The coordinates of the vertices of the image are E(2, 4) and F(5, 1). The vertex matrix for E F is

8. The reflection matrix for a reflection in the x-axis is

1 3 3 3 5 A1 4 , 2 , B 4 , 4 , C 4 , 4 , and

Multiply the vertex matrix for PQR by the rotation matrix to find the vertex matrix of the image. 7 0 1 6 6 2 3 7 1 0 3 7 7 6 6 2 The coordinates of the vertices of the image are P(3, 6), Q(7, 6), and R(7, 2). 12. The vertex matrix for quadrilateral STUV is 4 2 0 2 . 1 2 1 2 Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 4 2 0 2 8 4 0 4 2 1 2 1 2 2 4 2 4 The rotation matrix for a counterclockwise 0 1 rotation of 90° is . 0 1

Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 1 3 3 1 4 4 4 4 1 3 3 1 1 4 2 3 5 4 3 5 1 2 4 4 1

The vertex matrix for PQR is

The coordinates of the vertices of the image are X(6, 8), Y(12, 20), and Z(6, 10). 1 3 3 1 7. The vertex matrix for ABCD is . 2 3 5 4

21

3 . 5 Multiply the vertex matrix for L M by the rotation matrix to find the vertex matrix of the image. 2 3 1 5 0 1 0 1 5 2 3 1 The coordinates of the vertices of the image are L(1, 2) and M(5, 3). 11. The rotation matrix for a counterclockwise 0 1 . rotation of 270° is 1 0

3 6 3 6. The vertex matrix for XYZ is . 4 10 5 Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 3 6 3 6 12 6 2 4 10 5 8 20 10

The vertex matrix for L M is

5 13 3 9 6 6 The coordinates of the vertices of the image are D(1, 9), E(5, 9), F(3, 6), and G(3, 6).

10. The rotation matrix for a counterclockwise 0 1 rotation of 90° is . 1 0

Find the vertex matrix for the image. 0 0 0 0 1 5 3 3 1 6 6 6 6 3 3 0 0 9

The coordinates of the vertices of the image are H(5, 4), I(1, 1), J(3, 6), and K(7, 3).

3 3 . 0 0

5 3

0 . 1

The vertex matrix for HIJK is

Find the vertex matrix for the image. 1 2 3 0 5 3 2 2 2 . 2 4 1 3 2 1 1 1 1

10

Multiply the vertex matrix of the image due to dilation to find the vertex matrix of the final image. 8 4 0 4 2 4 2 4 0 1 2 4 2 4 8 4 0 0 4 1

The coordinates of the vertices of the image are S(2, 8), T(4, 4), U(2, 0) and V(4, 4).

332

13. The rose bed must be dilated by a scale factor of 1 2. The vertex matrix of the rose bed is

Find the vertex matrix for the image.

Multiply the vertex matrix by the scale factor to find the vertex matrix of the new rose bed plan.

3 7 5 1 1 2 1 3 7 5

3 7 5 1 2 2 2 2 1 3 7 2 2 2 5 2

65

2

25 25.

4 1

1 1

5 1 1 1

6 2 2 10 1 3

3 3 4 5

3 6 4 3 1 1 3 3

84

12 24 16 12 4 4 12 12

The coordinates of the vertices of the image are K(4, 8), L(12, 4), M(24, 4), N(16, 12), and O(12, 12). 23. The reflection matrix for a reflection in the y-axis 1 0 . is 0 1 2 4 Y is . The vertex matrix for X 2 1

6 6 2 . 2 1 1


3 6 4 3 . 1 1 3 3

21

The coordinates of the vertices of the image are M(1, 1), N(5, 3), O(5, 1), and P(1, 1). 18. The vertex matrix for trapezoid RSTU is

23

42 46 6 8

4

3 3 3 3 2 2 6 6 6 6 7 5 5 3

Multiply the vertex matrix by the scale factor to find the vertex matrix of the image.


21

3 3 3 3 . The translation matrix is 6 6 6 6 2 9

The coordinates of the vertices of the image are G(2, 1), H(2, 3), I(3, 4), and J(3, 5). 22. The vertex matrix for pentagon KLMNO is

1 4

27

1 2

The coordinates of the vertices of the image are J(6, 1), K(1, 4), and L(4, 1). 2 2 2 2 17. The vertex matrix for MNOP is . 7 9 7 5

2

1


0 1

3 3 3 6 7 1 4 4 4 5

21. The vertex matrix for quadrilateral GHIJ is 6 4 4 6 . 2 6 8 10

3 3 . 4 4 Find the vertex matrix for the image. 4 8

1 4

The coordinates of the vertices of the image are E(6, 6) and F(3, 8). 3 4 7 16. The vertex matrix for JKL is . 5 8 5

35

4 1 2 D 1 3 , 3 , E 0, 3 , and F 3 , 1 .

3 4

4 3 12 8 6 5 7 10 10 14

0 3 2 3 4 1 3 3 3 1 The coordinates of the vertices of the image are 1 3

4 1 2 2 6 3 1 3 5 5 6 8


4 3 . 5 7


65


The coordinates of the vertices of the image are A(12, 10), B(8, 10), and C(6, 14). 1 0 2 20. The vertex matrix for DEF is . 4 1 3

4 1 15. The vertex matrix for E F is . 1 3 The translation matrix is


Practice and Apply

41

19. The vertex matrix for ABC is

The new coordinates are (1.5, 0.5), (3.5, 1.5), (2.5, 3.5), and (0.5, 2.5). 14. All dimensions have been reduced by 1 2 , so the coordinates of the center after the changes have been made will be 1 2 (4, 4) (2, 2).

0 0 8 0 3 1 The coordinates of the vertices of the image are R(4, 1), S(0, 0), T(0, 3), and U(8, 1).

13 37 75 51.

Pages 509–511

6 6 6 6 6 6 2 2 2 2 2 2 1 1

23

6 6 6 6 . 2 2 2 2

Multiply the vertex matrix for X Y by the reflection matrix to find the vertex matrix of the image.

333

Chapter 9

10

2 4 2 4 0 2 1 1 2 1

Find the vertex matrix for the image. 1 3 3 4 4 4 7 3 1 3 2 3 2 2 3 1 1 1 The coordinates of the vertices of the image are V(7, 2), W(3, 2), and X(1, 3). 29. The rotation matrix for a counterclockwise 0 1 rotation of 90° is . 1 0

The coordinates of the vertices of the image are X(2, 2), and Y(4, 1). 24. The reflection matrix for a reflection in the line 0 1 y x is . 1 0

The vertex matrix for ABC is

2 3


Chapter 9

4 1

3 3 3 3 . 2 2 2 2

32 1 1

1 2

3 5 2 1

Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 1 4 2 0 2 0 6 3 12 6 3 1 1 4 4 1 3 3 12 12 3 The coordinates of the vertices of the image are P(3, 3), Q(12, 3), R(6, 12), S(0, 12), and T(6, 3).

33

23

4 V(2, 2), W 2 3 , 2 , and X 2, 3 .

28. The vertex matrix for VWX is

The coordinates of the vertices of the image are P(2, 3), Q(1, 1), R(1, 2), S(3, 2), and T(5, 1). 32. The vertex matrix for polygon PQRST is 1 4 2 0 2 . 1 1 4 4 1

The coordinates of the vertices of the image are

3 1 . 3 2

2

4 2 3

Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 2 1 3 3 2 2

33

Find the vertex matrix for the image. 3 3 3 3 3 1 4 2 0 2 2 2 2 2 2 1 1 4 4 1

The coordinates of the vertices of the image are H(9, 1), I(2, 6), J(4, 3), and K(2, 4). 3 3 1 27. The vertex matrix for VWX is . 3 3 2

3 2 3 3


The vertex matrix for quadrilateral HIJK is 9 2 4 2 . 4 1 6 3 Multiply the vertex matrix for quadrilateral HIJK by the reflection matrix to find the vertex matrix of the image. 9 2 4 2 1 0 9 2 4 2 0 1 1 6 3 4 1 6 3 4

Mutiply the vertex matrix for VWX by the reflection matrix to find the vertex matrix of the image. 0 1 3 3 1 3 3 2 1 0 3 3 3 2 3 1 The coordinates of the vertices of the image are V(3, 3), W(3, 1), and X(2, 3). 31. The vertex matrix for polygon PQRST is 1 4 2 0 2 . 1 1 4 4 1

The vertex matrix for VWX is

Multiply the vertex matrix for quadrilateral DEFG by the reflection matrix to find the vertex matrix of the image. 0 1 4 2 3 3 4 2 3 3 4 0 1 5 6 1 4 5 6 1 The coordinates of the vertices of the image are D(4, 5), E(2, 6), F(3, 1), and G(3, 4). 26. The reflection matrix for a reflection in the y-axis 1 0 is . 0 1

30. The reflection matrix for a reflection in the line 0 1 y x is . 1 0

The vertex matrix for quadrilateral DEFG is 4 2 3 3 . 5 6 1 4

3 1 . 3 2

The coordinates of the vertices of the image are V(3, 3), W(3, 1), and X(2, 3).

33

Multiply the vertex matrix for VWX by the rotation matrix to find the vertex matrix of the image. 0 1 3 3 1 3 3 2 1 0 3 3 2 1 3 3

The coordinates of the vertices of the image are A(3, 5), B(5, 0), and C(3, 1). 25. The reflection matrix for a reflection in the x-axis 0 1 is . 0 1

The vertex matrix for VWX is

0 1 3 5 3 5 3 5 0 1

5 0 1 . 3 5 3

Multiply the vertex matrix for ABC by the reflection matrix to find the vertex matrix of the image.

01 10 35

1 3 . 3 2

4 4 . 1 1

334

33. The reflection matrix for a reflection in the y-axis 1 0 is . 0 1

37. The rotation matrix for a counterclockwise 0 1 rotation of 90° is . 1 0

The vertex matrix for polygon PQRST is 1 4 2 0 2 . 1 1 4 4 1

The vertex matrix for STUV is

11

4 1

0 4

11

2 1

1 2 3 1 3

4 3

2 3 4 3

2 2 3 3 1 2 2 3 3 3

1

The reflection matrix for a reflection in the x-axis

10

0 . 1 Multiply the vertex matrix of the image by the reflection matrix to find the vertex matrix of the final image. is

1 1 . 2 4

1 0 0 1

Multiply the vertex matrix for PQR by the rotation matrix to find the vertex matrix of the image. 5 1 1 1 0 5 1 1 0 1 1 2 4 4 1 2

0 6

5 The vertex matrix for PQR is 1

11

3 . 10 Multiply the vertex matrix for M N by the rotation matrix to find the vertex matrix of the image. 0 1 12 3 1 10 1 12 3 0 1 10 The coordinates of the vertices of the image are M(1, 12), and N(10, 3). 36. The rotation matrix for a counterclockwise 1 0 rotation of 180° is . 0 1

121

8 10 3 4 4 5 The coordinates of the vertices of the image are A(1, 1), B(0, 6), C(8, 4), D(10, 4), and E(3, 5). 39. The vertex matrix for polygon ABCDEF is 3 2 2 3 2 2 . 1 4 4 1 2 2 Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 3 2 2 3 2 2 1 3 1 4 4 1 2 2

N is The vertex matrix for M

4 2 0 2 1 4 4 1 The coordinates of the vertices of the image are P(1, 1), Q(4, 1), R(2, 4), S(0, 4), and T(2, 1). 35. The rotation matrix for a counterclockwise 0 1 rotation of 90° is . 1 0

1 4 2 0 1 1 4 1

The vertex matrix for pentagon ABCDE is 6 4 4 5 1 . 0 8 10 3 1 Multiply the vertex matrix for pentagon ABCDE by the rotation matrix to find the vertex matrix of the image. 0 1 6 4 4 5 1 1 0 0 8 10 3 1

10

The coordinates of the vertices of the image are P(1, 1), Q(4, 1), R(2, 4), S(0, 4), and T(2, 1). 34. The rotation matrix for a counterclockwise 1 0 rotation of 180° is . 0 1 The vertex matrix for polygon PQRST is 1 4 2 0 2 . 1 1 4 4 1 Multiply the vertex matrix for PQRST by the rotation matrix to find the vertex matrix of the image.

6 5 1 . 1 3 3

The coordinates of the vertices of the image are S(1, 2), T(1, 6), U(3, 5), and V(3, 1). 38. The rotation matrix for a counterclockwise 0 1 rotation of 270° is . 1 0

0 2 4 1

2 4

21

Multiply the vertex matrix for STUV by the rotation matrix to find the vertex matrix of the iamge. 0 1 2 6 5 1 1 1 3 3 1 2 6 5 1 0 1 1 3 3

Multiply the vertex matrix for PQRST by the reflection matrix to find the vertex matrix of the image. 1 0 1 4 2 0 2 0 1 1 1 4 4 1

1 1 3

1 2 3

2 3 4 3

1 4 3 3 2 3 2 1 3 4 1 4 3 3 3

1 1 3 2 3 2 3

2 2 3 3 2 3 2 3 2 3 2 3

The coordinates of the vertices of the final image

2 2 2 2 D1, 1 3 , E 3 , 3 , and F 3 , 3 .

2 4 2 4 are A 1, 1 3 , B 3 , 3 , C 3 , 3 ,

The coordinates of the vertices of the image are P(5, 1), Q(1, 2), and R(1, 4).

335

Chapter 9

Multiply the vertex matrix for ABCDEF by the rotation matrix to find the vertex matrix of the image.

40. The vertex matrix for polygon ABCDEF is

31

2 4

3 2 2 . 1 2 2 The translation matrix is

2 4

10 10 31

5 5 5 5 5 5 . 2 2 2 2 2 2 Find the vertex matrix for the image. 3 2 2 3 2 2 5 5 5 5 5 5 1 4 4 1 2 2 2 2 2 2 2 2

3 8

31

14

21

5 2

2 1 1 7 6 2

5 6

The coordinates of the vertices of the final image are A(2, 1), B(5, 2), C(5, 6), D(2, 7), E(1, 6), and F(1, 2). 42. The rotation matrix for a counterclockwise 1 0 rotation of 180° is . 0 1

10

Chapter 9

1 . 0 50. B; since 26% are action movies and 14% are comedies, 60% of the movie titles are neither action movies nor comedies. 0.60(2500) 1500 So, 1500 movie titles are neither action movies nor comedies.

The vertex matrix for polygon ABCDEF is 3 2 2 3 2 2 . 1 4 4 1 2 2

1 1 1 1 1 . 4 4 4 4 4

0 . 1

46. A counterclockwise rotation of 90° could be used to create a floor plan with the house facing east. 0 1 The rotation matrix is . 1 0 47. A reflection in the line y x transforms (x, y) into (y, x). The matrix that performs this 0 1 operation is . 1 0 48. Matrices make it simpler for movie makers to move figures. Answers should include the following. • By using a succession of matrix transformations, an object will move about in a scene. • Sample answer: programming the animation in a screen saver 49. The rotation matrix for a 90° clockwise rotation is equivalent to a 270° counterclockwise rotation, or

Find the vertex matrix for the final image. 4 4 1 2 2 1 1 1 1 1 1 1 4 4 4 4 4 4 3 2 2 3 2 2

10


45. Imagine the y-axis in the middle of the plan. Then a reflection in the y-axis could be used to create a floor plan with the garage on the left. The 1 0 reflection matrix is . 0 1

1 2 2 3 2 2

4 2

6 4 4 2 4 4

4 8

4 2

4 8

0 Translate up 2 units using . 2 Combine the two operations into 0 x 1 0 . 2 0 1 y

62

44. Reflect in the y-axis using the matrix

43. Each footprint is reflected in the y-axis, then translated up two units.

The coordinates of the vertices of the final image are A(6, 2), B(4, 8), C(4, 8), D(6, 2), E(4, 4), and F(4, 4).

6 6 3 0 0 7 3 2 3 7 The coordinates of the vertices of the final image are A(3, 8), B(6, 7), C(6, 3), D(3, 2), E(0, 3), and F(0, 7). 41. The reflection matrix for a reflection in the line 0 1 y x is . 1 0 The vertex matrix for polygon ABCDEF is 3 2 2 3 2 2 . 1 4 4 1 2 2 Multiply the vertex matrix for ABCDEF by the reflection matrix to find the vertex matrix of the image. 0 1 3 2 2 3 2 2 1 0 1 4 4 1 2 2

Multiply the vertex matrix of the image by the scale factor to find the vertex matrix of the final image. 3 2 2 3 2 2 2 1 4 4 1 2 2

The rotation matrix for a counterclockwise 0 1 rotation of 90° is . 1 0 Multiply the vertex matrix of the image by the rotation matrix to find the vertex matrix of the final image. 0 1 8 7 3 2 3 7 1 0 3 6 6 3 0 0

3 2 2 1 2 2

2 4

3 2 2 3 2 2 1 4 4 1 2 2

83 76 36 23 30 70

2 4

336

Page 511

180(n 2) 180(8 2) ¬ n 8


51. First, graph ABC. Next, translate each vertex by , 1 unit left and 5 units down. Connect the v vertices to form ABC. 8

y

4 4

A

exterior angle of a 10-sided polygon is 10 or 36. Use the Interior Angle Formula to find the interior angle of a regular 10-sided polygon.

B O

4 8

360

B

A 8

¬135 57. The measure of an exterior angle of a regular 360 polygon is given by n. The measure of an

4

180(n 2) 180(10 2) ¬ n 10

8x

¬144 58. The two right triangles are similar. So, using the D E CD definition of similar polygons, AB BC . Solve for DE.

C C

D E CD AB BC

52. First, graph quadrilateral DEFG. Next, translate each vertex by w , 7 units left and 8 units up. Connect the vertices to form quadrilateral DEFG.

34 .5 DE (1.75) 0.75

DE 80.5 The tree is 80.5 m tall.

y

E 8

D 8

CD DE (AB) BC

4

4

F E

Chapter 9 Study Guide and Review

G O

4

4 D

x

F

Vocabulary and Concept Check 1. 2. 3. 4. 5. 6. 7. 8.

G 53. Compare WX and WX. Note that the scale factor is negative since the image appears on the opposite side of the center with respect to the preimage. image length

scale factor ¬ preimage length 2un its r ¬ 4units r ¬1 2

false; center true false; component form false; magnitude false; center of rotation true false; scale factor false; resultant vector


Since 0 r 1, the dilation is a reduction. 54. The measure of an exterior angle of a regular 360 polygon is given by n. The measure of an 36 0 exterior angle of a 5-sided polygon is 5 or 72. Use the Interior Angle Formula to find the interior angle of a regular 5-sided polygon.

9. Use the vertical grid lines to find images of each vertex of ABC so that each vertex of the image is the same distance from the x-axis as the vertex of the preimage or use (a, b) → (a, b) A(2, 1) → A(2, 1) B(5, 1) → B(5, 1) C(2, 3) → C(2, 3) Draw triangles ABC and ABC.

180(n 2) 180(5 2) ¬ n 5

¬108 55. The measure of an exterior angle of a regular 360 polygon is given by n. The measure of an 36 0 exterior angle of a 6-sided polygon is 6 or 60. Use the Interior Angle Formula to find the interior angle of a regular 6-sided polygon.

y C

B O

180(n 2) 180(6 2) ¬ n 6

A A

x

B

C

¬120 56. The measure of an exterior angle of a regular 360 polygon is given by n . The measure of an 36 0 exterior angle of a 8-sided polygon is 8 or 45. Use the Interior Angle Formula to find the interior angle of a regular 8-sided polygon.

337

Chapter 9

10. Use the transformation (a, b) → (b, a). W(4, 5) → W(5, 4) Y(3, 3) → Y(3, 3) X(1, 5) → X(5, 1) Z(6, 3) → Z(3, 6) Draw parallelograms WXYZ and WXYZ. W

14. This translation moved each vertex 1 unit to the right and 3 units down. X(2, 5) → X(2 1, 5 3) or X(3, 2) Y(1, 1) → Y(1 1, 1 3) or Y(2, 2) Z(5, 1) → Z(5 1, 1 3) or Z(6, 2) Draw XYZ and XYZ.

y

X

y X

Y

Z

X

X x

O

Z

Y Y W

Z

Y 15.

Z 11. Use the vertical grid lines to find images of each vertex of rectangle EFGH such that each vertex of the image is the same distance from the line x 1 as the vertex of the preimage. E(4, 2) → E(6, 2) G(0, 4) → G(2, 4) F(0, 2) → F(2, 2) H(4, 4) → H(6, 4) Draw rectangles EFGH and EFGH. y

x

O

y

B D

C

B

x

E

F

F

E

H

G

G

H

Reflection in x-axis: B(3, 5) → (−3, −5) C(3, 3) → (3, 3) D(5, 3) → (5, 3) Reflection in the y-axis: (3, 5) → B(3, 5) (3, 3) → C(3, 3) (5, 3) → D(5, 3) The angle of rotation is 180°.

12. This translation moved each vertex 4 units to the left and 4 units down. E(2, 2) → E(2 4, 2 4) or E(2, 2) F(6, 2) → F(6 4, 2 4) or F(2, 2) G(4, 2) → G(4 4, 2 4) or G(0, 6) H(1, 1) → H(1 4, 1 4) or H(3, 5) Draw quadrilaterals EFGH and EFGH. y E F

16.

H O

x

F

G Reflection in line y x: F(0, 3) → (3, 0) G(1, 0) → (0, 1) H(4, 1) → (1, 4) Reflection in line y x: (3, 0) → F(0, 3) (0, 1) → G(1, 0) (1, 4) → H(4, 1) The angle of rotation is 180°.

H G 13. This translation moved each vertex 2 units to the right and 4 units up. S(3, 5) → S(3 2, 5 4) or S(1, 1). T(1, 1) → T(1 2, 1 4) or T(1, 3) Draw S T and S T . y T

x

S

S

Chapter 9

G H

E F

x

F

x

OH

y

y

G

O

D

C

1

x

O

T

x

O

338

17.

24. No; let m1 represent one interior angle of the regular pentagon. Use the Interior Angle Formula.

y

N M

180(n 2)

m1 ¬n

N

180(5 2)

¬5 ¬108 Since 108 is not a factor of 360, a pentagon will not tessellate the plane. 25. Yes; the measure of an interior angle of an equilateral triangle is 60, which is a factor of 360, so an equilateral triangle will tessellate the plan. 26. No; let m1 represent one interior angle of the regular decagon. Use the Interior Angle Formula.

M L

L O

x

180(n 2)

Reflection in line y x: L(2, 2) → (2, 2) M(5, 3) → (3, 5) N(3, 6) → (6, 3) Reflection in the x-axis: (2, 2) → L(2, 2) (3, 5) → M(3, 5) (6, 3) → N(6, 3) The angle of rotation is 90° counterclockwise. 18. The figure has rotational symmetry of order 9 because there are 9 rotations less than 360° (including 0 degrees) that produce an image indistinguishable from the original.

m1 ¬n 180(10 2)

27.

360° magnitude ¬ ord er 36 0° ¬9 ¬40° The magnitude of the symmetry is 40°.

28.

36 0° 19. magnitude ¬ order 36 0° ¬ 9 ¬40° The magnitude of the symmetry is 40°. Vertex 2 is moved 5 positions, or 5(40°) 200°.

29.

30.

360° 20. magnitude ¬ ord er 36 0° ¬ 9 ¬40° The magnitude of the symmetry is 40°. Divide 280° by the magnitude of the rotational symmetry. 28 0° 40° 7 positions Vertex 5 is moved 7 positions, or to the original position of vertex 7. 21. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. 22. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is also regular since it is formed by only one type of regular polygon. 23. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles.

¬10 ¬144 Since 144 is not a factor of 360, a decagon will not tessellate the plane. CD 8, r 3 Use the Dilation Theorem. CD r(CD) CD (3)(8) CD 24 CD 2 3 , r 6 Use the Dilation Theorem. CD r(CD) CD (6)2 3 CD 4 CD 24, r 6 Use the Dilation Theorem. CD ¬r(CD) 24 ¬(6)(CD) 4 ¬CD 1 0 CD 60, r 3 Use the Dilation Theorem. CD ¬r(CD) 1 0 60 ¬ 3 (CD)

18 ¬CD 31. CD 12, r 5 6 Use the Dilation Theorem. CD r(CD) CD 5 6 (12)

CD 10

5 5 5 32. CD 2 ,r 4 Use the Dilation Theorem. CD ¬r(CD)

5 5 5 2 ¬ 4 (CD)

22 ¬CD 33. Find P, Q, and R using the scale factor, r 2. Preimage (x, y) Image (2x, 2y) P(1, 3) P(2, 6) Q(2, 2) Q(4, 4) R(1, 1) R(2, 2)

339

Chapter 9

34. Find E, F, G, and H using the scale factor, r 2. Preimage (x, y) Image (2x, 2y) E(3, 2) E(6, 4) F(1, 2) F(2, 4) G(1, 2) G(2, 4) H(3, 2) H(6, 4)

Graph AB to determine how to find the direction. Draw a right triangle that has AB as its hypotenuse and an acute angle at A. y

A

x

35. Find the change in x-values and the corresponding change in y-values. AB ¬x2 x1, y2 y1 ¬0 (3), 2 (2) ¬3, 4 36. Find the change in x-values and the corresponding change in y-values. CD ¬x2 x1, y2 y1 ¬4 4, 2 (2) ¬8, 4 37. Find the change in x-values and the corresponding change in y-values. EF ¬x2 x1, y2 y1 ¬1 1, 4 (4) ¬0, 8 38. Find the magnitude using the Distance Formula. AB ¬ (x2 x1)2 (y2 y1)2 2 ( ¬ [9 (6)] 3 4)2 ¬ 58

B

y y

2 1 tan A ¬ x x 2

1

2 5 ¬ 5 8 7 ¬ 13

7 mA ¬tan1 13

¬28.3 A vector in standard position that is equal to AB forms a 28.3° angle with the negative x-axis in the third quadrant. So it forms a 180 28.3 or 208.3° angle with the positive x-axis. Thus, AB has a magnitude of 218 or about 14.8 units and a direction of about 208.3°. 40. Find the magnitude using the Distance Formula. AB ¬ (x2 x1)2 (y2 y1)2 ¬ [15 (14 )]2 ( 5 2) 2 ¬ 890 ¬29.8 Graph AB to determine how to find the direction. Draw a right triangle that has AB as its hypotenuse and an acute angle at A.

¬7.6 Graph AB to determine how to find the direction. Draw a right triangle that has AB as its hypotenuse and an acute angle at A. y

A

y

10 x

A

x

10

20

B

10

B y y

2 1 tan A ¬ x x 2

y y

1

2 1 tan A ¬ x x

3 4 ¬ 9 (6)

2

7 ¬ 29

mA ¬tan1 7 3 ¬66.8 A vector in standard position that is equal to AB forms a 66.8° angle with the negative x-axis in the third quadrant. So it forms a 180 66.8 or 246.8° angle with the positive x-axis. Thus, AB has a magnitude of 58 or about 7.6 units and a direction of about 246.8°. 39. Find the magnitude using the Distance Formula. AB ¬ (x2 x1)2 (y2 y1)2

7 mA ¬tan1 29

¬13.6 A vector in standard position that is equal to AB forms a 13.6° angle with the positive x-axis in the fourth quadrant. So it forms a 360 13.6 or 346.4° angle with the positive x-axis. Thus, AB has a magnitude of 890 or about 29.8 units and a direction of about 346.4°. 41. Find the magnitude using the Distance Formula. AB ¬ (x x1)2 (y2 y1)2 2

¬ (5 8)2 (2 5)2 ¬ 218 ¬14.8 Chapter 9

1

5 2 ¬ 15 ( 14)

¬7 3

¬ (45 16)2 (0 40)2 ¬ 5321 ¬72.9

340

Graph AB to determine how to find the direction. Draw a right triangle that has AB as its hypotenuse and an acute angle at A. y

The vertex matrix for DEF is

10

B

10 10


y2 y1 tan A ¬ x2 x1 0 40 ¬ 45 16 40 ¬ 61 40 mA ¬tan1 61

92

2 2 . 5 5


Multiply the vertex matrix for DEF by the reflection matrix to find the vertex matrix of the image. 2 5 4 3 0 2 0 1 3 0 2 2 5 4 1 0

Page 517 1. isometry 3. scalar 5. D C

The coordinates of the vertices of the image are D(2, 3), E(5, 0), and F(4, 2). 45. The rotation matrix for a counterclockwise 0 1 . rotation of 270° is 1 0

44. The reflection matrix for a reflection in the line 0 1 y x is . 1 0 3 0 2 The vertex matrix for DEF is 2 5 4 .

10

Multiply the vertex matrix of the image by the scale factor to find the vertex matrix of the final image. 8 2 1 6 16 4 2 12 2 1 3 0 3 2 6 0 6 The coordinates of the vertices of the final image are W(16, 2), X(4, 6), Y(2, 0), and Z(12, 6).

The coordinates of the vertices of the image are 12 1 6 8 8 D 5 , 5 , E(0, 4), and F 5 , 5 .

8 5 16 4 5

6 0

Multiply the vertex matrix for WXYZ by the rotation matrix to find the vertex matrix of the image. 1 0 8 2 1 6 8 2 1 6 0 1 1 3 0 3 1 3 0 3

Multiply the vertex matrix by the scale factor to find the vertex matrix of the image. 0

The coordinates of the vertices of the image are D(6, 8), E(3, 1), and F(1, 10). 3 0 2 43. The vertex matrix for DEF is 2 5 4 .

12 0 2 5 5 4 8 5

4 2 2 2 11 3 5 5 5 5 3 6

1 1

11 3 6 0 11 3 6 3 6 0 1 3 6 0 The coordinates of the vertices of the final image are P(11, 3), Q(3, 6), and R(6, 0). 47. The rotation matrix for a counterclockwise 1 0 . rotation of 180° is 0 1 The vertex matrix for WXYZ 8 2 1 6 is . 1 3 0 3

3 6

52

The reflection matrix for a reflection in the x-axis 1 0 . is 0 1 Multiply the vertex matrix of the image by the reflection matrix to find the vertex matrix of the final image.

3 3 . 6 6 Find the vertex matrix for the image. 3 0 2 3 3 3 6 3 1 2 5 4 6 6 6 8 1 10 The translation matrix is

Find the vertex matrix of the image.

¬33.3 A vector in standard position that is equal to AB forms a 33.3° angle with the negative x-axis in the third quadrant. So it forms a 180 33.3 or 213.3° angle with the positive x-axis. or about Thus, AB has a magnitude of 5321 72.9 units and a direction of about 213.3°. 3 0 2 42. The vertex matrix for DEF is 2 5 4 .

3 4 5 2

20

The coordinates of the vertices of the image are D(2, 3), E(5, 0), and F(4, 2). 9 1 4 46. The vertex matrix for PQR is . 2 1 5

20x

10

0 2 . 5 4

Multiply the vertex matrix for DEF by the rotation matrix to find the vertex matrix of the image. 2 5 4 3 0 2 0 1 3 0 2 2 5 4 1 0

A

20

3 2

2. uniform 4. E 6. BCA

341

Chapter 9

7. First, graph PQR. Next, translate each vertex right 3 units and up 1 unit. Connect the vertices to form PQR. P(3, 5) → P(3 3, 5 1) or P(0, 6) Q(2, 1) → Q(2 3, 1 1) or Q(1, 2) R(4, 2) → R(4 3, 2 1) or R(1, 3)

11.

Reflection in line y x: A(3, 2) → (2, 3) B(1, 1) → (1, 1) C(3, 1) → (1, 3) Reflection in line y x: (2, 3) → A(3, 2) (1, 1) → B(1, 1) (1, 3) → C(3, 1) The angle of rotation is 180°.

R Q Q x

12.

y R

8. First, graph parallelogram WXYZ. Next, translate each vertex up 5 units and left 3 units. Connect the vertices to form WXYZ. W(2, 5) → W(2 3, 5 5) or W(5, 0) X(1, 5) → X(1 3, 5 5) or X(2, 0) Y(2, 2) → Y(2 3, 2 5) or Y(1, 3) Z(1, 2) → Z(1 3, 2 5) or Z(4, 3)

T

x

Y

X

W

9. First, graph F G . Next, translate each vertex left 4 units and down 1 unit. Connect the vertices to form F G . F(3, 5) → F(3 4, 5 1) or F(1, 4) G(6, 1) → G(6 4, 1 1) or G(2, 2) y

13.

F

14.

F

x

O

15.

G G 10.

y

L

K

16.

J x

O

J 17. K

L

Reflection in y-axis: J(1, 2) → (1, 2) K(3, 4) → (3, 4) L(1, 4) → (1, 4) Reflection in x-axis: (1, 2) → J(1, 2) (3, 4) → K(3, 4) (1, 4) → L(1, 4) The angle of rotation is 180°.

Chapter 9

x

R T

X O Z

W

S OS

y

Y

Z

C

B

A

P y

O

A

B

x

P

R

y

C

Reflection in y-axis: R(1, 6) → (1, 6) S(1, 1) → (1, 1) T(3, 2) → (3, 2) Reflection in line y x: (1, 6) → R(6, 1) (1, 1) → S(1, 1) (3, 2) → T(2, 3) The angle of rotation is 90° clockwise or 270° counterclockwise. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is uniform because at every vertex there is the same combination of shapes and angles. The tessellation is also semi-regular since more than one regular polygon is used. Yes; the pattern is a tessellation because at the different vertices the sum of the angles is 360°. The tessellation is not uniform because the number of angles at the vertices varies. MN 5, r 4 Use the Dilation Theorem. MN r(MN) MN (4)(5) MN 20 MN 8, r 1 4 Use the Dilation Theorem. MN r(MN) MN 1 4 (8)

MN 2

342

18. MN 36, r 3 Use the Dilation Theorem. MN ¬r(MN) 36 ¬(3)(MN) 12 ¬MN 19. MN 9, r 1 5 Use the Dilation Theorem. MN r(MN)

24. The distance Gunja must travel can be found by multiplying the distance measured on the map by the scale factor. 150 mi 2.25 in. 1 in. 337.5 mi

Gunja must travel 337.5 mi. 25. A; A reflection of (3, 4) in the x-axis gives (3, 4). A reflection of (3, 4) in the origin gives (3, 4). A reflection of (3, 4) in the y-axis gives (3,4). A reflection of (3, 4) in the origin gives (3, 4). Only choice A, a reflection in the x-axis, gives (3, 4).

MN 1 5 (9) MN 9 5 20. MN 20, r 2 3 Use the Dilation Theorem. MN ¬r(MN)


20 ¬2 3 (MN)

30 ¬MN 29 3 21. MN 5 , r 5 Use the Dilation Theorem. MN ¬r(MN)

Pages 518–519 1. D 2. A; both C E and D F are at an angle of 70° from the line AB, so they are parallel. 3. D; the congruence of a single pair of opposite sides is not sufficient proof that QRST is a parallelogram. 4. B; in a reflection in the y-axis, x-coordinates become their opposite, so (4, 2) → (4, 2). 5. D; parallelogram JKLM can be thought of as parallelogram ABCD transformed by having all of its points moved the same distance in the same direction, or translated. 6. B; congruence transformations preserve angle and distance measure, collinearity, and betweenness of points. Orientation is not necessarily preserved. 7. A; a 180° rotation of ABC about point C on line m maps ABC to ABC. 8. The top and bottom sides of the hexagon must be parallel and have the same length. So, the bottom side must have length 2 and slope 0. The coordinates of the missing vertex are (1, 2). 9. The triangle is isosceles, so the missing angle is x°. The sum of the interior angles of a triangle is 180°. Find x. 2x° x° x° ¬180° 4x° ¬180° x° ¬45° So, x 45. 10. The two right triangles are similar. So, using the AC B C . definition of similar polygons, CE CD Use the Pythagorean Theorem to find CE. CE ¬ (CD)2 (DE )2 2 ¬ 100 452 ¬5 481 Find x.

29 3 5 ¬ 5 (MN) 29 3 ¬MN

22. Find the magnitude of the resultant vector. v ¬ x2 y2 ¬ (3)2 22 ¬ 13 ¬3.6 The resultant vector lies in the second quadrant. Find the direction. y tan ¬x ¬2 3

m ¬tan12 3 ¬33.7 The resultant vector forms a 33.7° angle with the negative x-axis in the second quadrant. So it forms a 180 33.7 or 146.3° angle with the positive x-axis. Thus, v has a magnitude of 13 or about 3.6 units and a direction of about 146.3°. 23. Find the magnitude of the resultant vector. 2 y2 w ¬ x ¬ (6)2 (8)2 ¬10 The resultant vector lies in the third quadrant. Find the direction. y tan ¬x 8 ¬ 6

¬4 3 m ¬tan14 3 ¬53.1 The resultant vector forms a 53.1° angle with the negative x-axis in the third quadrant. So it forms a 180 53.1 or 233.1° angle with the positive x-axis. Thus, w has a magnitude of 10 units and a direction of about 233.1°.

AC B C ¬ CE CD x 30 0 ¬ 100 5 481

x ¬329 To the nearest meter, the length of the cable is 329 m.

343

Chapter 9

11. Given: AB A C , D A A E Prove: ABD ACE Proof:

12b. Find Q, R, S, and T using the scale factor, r 2. Preimage (x, y) Image (2x, 2y)

A

B

D

E

C

Q(2, 2)

Q(4, 4)

R(2, 4)

R(4, 8)

Statements

Reasons

S(3, 2)

S(6, 4)

1. A B A C , A D A E

1. Given

T(3, 4)

T(6, 8)

2. ABD ACE ADE AED

2. Isos. Thm.

R

3. ADB and ADE are supplementary. AEC and AED are supplementary.

3. If 2 form a linear pair, then they are suppl.

4. ADB AEC

4. suppl. to are .

5. ABD ACE

5. AAS

12a. 8

R 4 8

4

O

S

4

4 8

O

y

Q 8x

4

4 8

T

12c. Multiply the x- and y-coordinates of each vertex by the scale factor; Q(2, 2) becomes (2 2, 2 2) or Q(4, 4). 12d. Enlargements and reductions preserve the shape of the figure. Congruence transformations preserve collinearity, betweenness of points, and angle and distance measures.

Q 8x

T

8

Chapter 9

4

S

y

4

8

344

Chapter 10 Circles Page 521 1.

Getting Started

10.

4p ¬72 9 9 4p ¬9(72) 4 9 4

b

b 4ac x ¬ 2a

p ¬162

x ¬ 2(1)

6.3p 15. 75 ¬ 6.3 6.3

4 56 x ¬ 2

p ¬2.5

4 2 14 x ¬ 2

3x 12 ¬8x 3x 12 3x ¬8x 3x 12 ¬5x

x ¬2 14 x ¬5.7, 1.7 11. 3x2 2x 4 0 Use the Quadratic Formula. a 3, b 2, c 4

12 5 x 5 ¬ 5 12 5 ¬x or x ¬2.4

4. 7(x 2) ¬3(x 6) 7x 14 ¬3x 18 7x 3x ¬18 14 4x ¬32

b b 4ac x 2a 2

(2) (2) 4(3)(4) x 2(3) 2

2 52 x 6 2 2 13 x

4 x 32 4 ¬ 4

x ¬8 5. C ¬2pr

6

1 13 x 3

2pr C ¬ 2p 2p C ¬r 2p

6.

2

(4) (4)2 4(1)(10 )

2. 6.3p ¬15.75

3.

x2 4x ¬10 x2 4x 10 ¬0 Use the Quadratic Formula. a 1, b 4, c 10

x 1.5, 0.9 12.

x2 ¬x 15 x 15 ¬0 Use the Quadratic Formula. a 1, b 1, c 15 x2

C r ¬ 6.28 C 6.28r ¬6.28 6.28

b b 4ac x 2a 2

6.28r ¬C 7. c2 ¬a2 b2 172 ¬82 x2 289 ¬64 x2 225 ¬x2

(1) (1) 4(1)(15 ) x 2(1) 2

1 61 x 2

x 4.4, 3.4

225 ¬ x2

13.

15 ¬x

c2 ¬a2 b2 102 ¬62 x2 100 ¬36 x2 64 ¬x2 64 ¬x 2 8 ¬x 9. c2 ¬a2 b2 (6x)2 ¬722 722 36x2 ¬5184 5184 36x2 ¬10,368 8.

2x2 x ¬15 2x2 x 15 ¬0 Use the Quadratic Formula. a 2, b 1, c 15 b b 4ac x 2a 2

1 1 4(2)(1 5) x 2(2) 2

1 121 x 4 11 1 x 4 x 2.5, 3

2 10,368 36x 36 ¬ 36

x2 ¬288 x ¬288 x ¬17.0

10-1 Circles and Circumference Page 524 Geometry Activity: Circumference Ratio 1. See students’ work. 2. Each ratio should be near 3.1. 3. C 3.14d

345

Chapter 10

18. Two chords are shown: B E or C D . 19. B E is the only chord that goes through the center, so B E is a diameter. 20. F A is a radius not contained in a diameter. 21. The circle has its center at R, so it is named circle R, or R. 22. Six radii are shown: R T , R U , R V , R W , R X , or R Z . 23. Three chords are shown: Z V , T X , or W Z . 24. T X or W Z are the chords that go through the center, so T X and W Z are diameters. 25. R U and R V are radii not contained in a diameter. 26. d 2r d 2(2) or 4 ft

Pages 525–526 Check for Understanding 1. Sample answer: The value of is calculated by dividing the circumference of a circle by the diameter. 2. d 2r, r 1 2d 3. Except for a diameter, two radii and a chord of a circle can form a triangle. The Triangle Inequality Theorem states that the sum of two sides has to be greater than the third. So, 2r has to be greater than the measure of any chord, but 2r is the measure of the diameter. So the diameter has to be longer than any other chord of the circle. 4. The circle has its center at E, so it is named circle E, or E. 5. Four radii are shown: E A , E B , E C , or E D . 6. Three chords are shown: A B , A C , or B D . 7. A C and B D are chords that go through the center, so A C and B D are diameters.

27. r 1 2d r 1 2 (5) or 2.5 ft 28. TR 1 2 (TX)

8. r 1 2d

TR 1 2 (120) or 60 cm

29. ZW 2RZ ZW 2(32) or 64 in. or 5 ft 4 in. 30. U R and R V are both radii. RV UR RV 18 in. 31. X T is a diameter and U R is a radius.

r 1 2 (12) or 6

The radius is 6 mm. 9. d 2r d 2(5.2) or 10.4 The diameter is 10.4 in. 10. Since the radius of Z is 7, XZ 7. Z Y is part of radius X Z . XY YZ ¬XZ 2 YZ ¬7 YZ ¬5 11. Since the radius of W is 4, IW 4 and WY 4. IX is part of diameter IY . IX XY ¬IW WY IX 2 ¬4 4 IX ¬6 12. IC IW WY XZ ZC XY IC 4 4 7 7 2 IC 20 13. d 2r d 2(5) or 10 m C d C (10) or about 31.42 m 14. C ¬d 2368 ¬d

UR 1 2 XT UR 1 2 (1.2) or 0.6 m

32. AZ CW AZ 2 33. A X is a radius of A, and Z X is part of A X . AZ ZX ¬AX 2 ZX ¬1 2 (10)

ZX ¬3 34. BZ is a radius of B, and B X is part of B Z . ZX BX ¬BZ 3 BX ¬1 2 (30)

3 BX ¬15 BX ¬12 35. BY BX BY 12 36. YW ZX YW 3 37. AC AZ ZW WC AC 2 30 2 or 34 38. FG GH FG 10 39. FH FG GH FH 10 10 or 20 40. GL GH GL 10 41. G L is a diameter of J, so GL 10. J G is a radius of J.

2368 ¬d

753.76 ¬d d ¬753.76 ft r ¬1 2d r ¬1 2 (753.76) or 376.88 ft

15. B; C d C ¬(9) or 9 mm

Pages 526–527

Practice and Apply

16. The circle has its center at F, so it is named circle F, or F. 17. Three radii are shown: F A , F B , or F E .

Chapter 10

GJ 1 2 (GL) GJ 1 2 (10) or 5

346

42. J L is a radius of J.

53. The diameter of the circle is the same as the hypotenuse of the right triangle. d2 32 42 d2 25 d 25 or 5 ft C d C (5) or 5 ft 54. The diameter of the circle is the same as the hypotenuse of the right triangle. d2 102 102 d2 200 d 200 or 102 in. C d C (102 ) or 102 in. 55. The diameter of the circle is the same as the hypotenuse of the right triangle. d2 (4 2)2 (4 2)2 2 d 64 d 64 or 8 cm C d C (8) or 8 cm 56. 1; This description is the definition of a radius. 57. 0; The longest chord of a circle is the diameter, which contains the center. 58. C 2r C 2(800) or about 5026.5 ft 59. 800 200 600 800 300 500 The range of values for the radius of the explosion circle is 500 to 600 ft. 60. C 2r C 2(500) or about 3142 C 2(600) or about 3770 The least and maximum circumferences are 3142 ft and 3770 ft, respectively. 61. Let r the radius of O. x2 y2 ¬r2 p2 t2 ¬r2 x2 y2 p2 t2 ¬288 Substitute r2 for x2 y2 and r2 for p2 t2. r2 r2 ¬288 2r2 ¬288 r2 ¬144 r ¬12 C 2r C 2(12) or 24 units 62. Sample answer: about 251.3 feet. Answers should include the following. • The distance the animal travels is approximated by the circumference of the circle. • The diameter for the circle on which the animal is located becomes 80 2 or 78. The circumference of this circle is 78. Multiply by 22 to get a total distance of 22(78) or 5391 feet. This is a little over a mile.

JL 1 2 (10) or 5

43. JL is a diameter of K, so JL 5. K J is a radius of K. JK 1 2 JL JK 1 2 (5) or 2.5

44. d ¬2r d ¬2(7) or 14 mm C ¬d C ¬(14) or about 43.98 mm 45. r ¬1 2d r ¬1 2 (26.8) or 13.4 cm C ¬d C ¬(26.8) or about 84.19 cm

46.

C ¬d 26 ¬d 26 ¬d or d 26 mi r ¬1 2d r ¬1 2 (26) or 13 mi

47.

C ¬d 76.4 ¬d 76 .4 ¬d

24.32 d or d 24.32 m r 1 2d r 1 2 (24.32) or 12.16 m 48. r 1 2d 1 1 r 1 2 12 2 or 6 4 yd C d C 121 2 or about 39.27 yd

49. d 2r 1 d 263 4 or 13 2 in. C d C 131 2 or about 42.41 in. 50. r 1 2d r 1 2 (2a) or a

C d C (2a) or about 6.28a 51. d 2r d 2a 6 or about 0.33a

C 2r

C 2a 6 or about 1.05a 52. The diameter of the circle is the same as the hypotenuse of the right triangle. d2 162 302 d2 1156 d 1156 or 34 m C d C (34) or 34 m

347

Chapter 10

mC ¬tan1 1 2

63. Let r the radius of C. Then 2r the radius of B, and 4r the radius of A. sum of circumferences ¬2r 2(2r) 2(4r) 42 ¬2r 4r 8r 42 ¬14r 3 ¬r AC r 2(2r) 4r AC 3 2(2 3) 4(3) AC 3 12 12 or 27

¬27 The magnitude is about 44.7 and the direction is about 27°. 70. AB |k|(AB) AB 6(5) AB 30 71. AB |k|(AB) AB 1.5(16) AB 24 72. AB ¬|k|(AB)

100d 64. A; k% of gasoline has been pumped.

65. Small circle: C 2r C 2(5) or 10 Medium circle: r 5 5 or 10 C 2r C 2(10) or 20 Large circle: r 5 5 5 or 15 C 2r C 2(15) or 30 The circumferences from least to greatest are 10, 20, and 30.

2 ¬1 23 ¬1 3

73. Given: R Q bisects SRT Prove: mSQR mSRQ

S Proof: Statements RQ bisects SRT. SRQ QRT mSRQ mQRT mSQR mT mQRT 5. mSQR mQRT 6. mSQR mSRQ 1. 2. 3. 4.

Page 528 Maintain Your Skills 2 42 | ¬1 66. |AB

¬17 ¬4.1 mA ¬tan1 4 1 ¬76 The magnitude is about 4.1 and the direction is about 76°. 2 92 | ¬4 67. |V ¬97 ¬9.8

Q

Reasons 1. 2. 3. 4.

Given Def. of bisector Def. of Exterior Angle Theorem 5. Def. of Inequality 6. Substitution

F . Therefore, the missing 74. a is the midpoint of O coordinates are (2a, 0). 75. x 2x ¬180 Linear pair 3x ¬180 x ¬60 76. 2x 3x ¬90 Lines are perpendicular. 5x ¬90 x ¬18 77. (3x x) 2x ¬180 Linear pair 6x ¬180 x ¬30 78. 3x 5x ¬180 Linear pair 8x ¬180 x ¬22.5 79. 3x ¬90 lines form 2 rt . x ¬30 80. x x x ¬360 3x ¬360 x ¬120

mV ¬tan1 9 4

¬66 The magnitude is about 9.8 and the direction is about 66°. | ¬ 68. |AB (7 4 )2 (2 2 2)2 2 2 ¬ 3 2 0 ¬409 ¬20.2 2 22 tanA ¬ 74 20 ¬ 3 20 mA ¬tan1 3

¬81 The magnitude is about 20.2 and the direction is about 81°. | ¬ 69. |CD (40 0)2 (0 (20)) 2 2 2 ¬ 40 20 ¬2000 ¬44.7 0 (20)

tanC ¬ 40 0 20 1 ¬ 40 or 2

Chapter 10

R

348

T

12. C 2r C 2(12) or 24 Let arc length.

10-2 Angles and Arcs

60 36 0 ¬ 24

Pages 532–533 Check for Understanding 1. Sample answer:

60 36 0 (24) ¬

A C

4 ¬ The length of TR is 4 units or about 12.57 units. 13. Sample answer: 25%(360°) 90°, 23%(360°) 83°, 28%(360°) 101°, 22%(360°) 79°, 2%(360°) 7°

90 110 160 B

110, AB, BC, AC, ABC, BCA, CAB; mAB mBC 160, mAC 90, mABC 270, 250, mCAB 200 mBCA 2. A diameter divides the circle into two congruent arcs. Without the third letter, it is impossible to know which semicircle is being referenced. 3. Sample answer: Concentric circles have the same center, but different radius measures; congruent circles usually have different centers but the same radius measure. 4. MCN and NCL are a linear pair. mMCN mNCL ¬180 60 mNCL ¬180 mNCL ¬120 5. MCR and RCL are a linear pair. mMCR mRCL ¬180 (x 1) (3x 5) ¬180 4x 4 ¬180 4x ¬176 x ¬44 Use the value of x to find mRCL. mRCL ¬3x 5 ¬3(44) 5 ¬132 5 or 137 6. Use the value of x to find mRCM. From Exercise 5, x ¬44. mRCM ¬x 1 ¬44 1 or 43 7. RCN is composed of adjacent angles, RCM and MCN. mRCN mRCM mMCN 43 60 or 103 mBAC. 8. BC is a minor arc, so mBC BAC ¬EAD mBAC ¬mEAD ¬mEAD mBC ¬42 mBC 9. CBE is a semicircle. 180 mCBE is by using 10. One way to find mEDB EDC and CB. EDC is a semicircle. mEDC mCB mEDB mEDB 180 42 or 222 is by using 11. One way to find mCD CDE and DE. CDE is a semicircle. mDE ¬mCDE mCD mCD 42 ¬180 ¬138 mCD

Pages 533–535 Practice and Apply 14. AGC and CGB are a linear pair. mAGC mCGB ¬180 60 mCGB ¬180 mCGB ¬120 15. AGC and BGE are vertical angles. mBGE mAGC mBGE 60 16. AGD is a right angle. mAGD 90 17. One way to find mDGE is by using AGD and BGE. AGB is a straight angle. mAGD mDGE mBGE ¬mAGB 90 mDGE 60 ¬180 mDGE ¬30 18. CGD is composed of adjacent angles, CGA and AGD. mCGD mCGA mAGD mCGD 60 90 mCGD 150 19. AGE is composed of adjacent angles, AGD and DGE. mAGE mAGD mDGE mAGE 90 30 mAGE 120 20. ZXV and YXW are vertical angles. mZXV ¬mYXW 2x 65 ¬4x 15 50 ¬2x 25 ¬x Use the value of x to find mZXV. mZXV 2x 65 2(25) 65 50 65 or 115 21. Use the value of x to find mYXW. From Exercise 20, x 25. mYXW 4x 15 4(25) 15 100 15 or 115 22. ZXY and ZXV are a linear pair. mZXY mZXV ¬180 mZXY 115 ¬180 mZXY ¬65 23. ZXY and VXW are vertical angles. VXW ¬ZXY mVXW ¬mZXY mVXW ¬65

349

Chapter 10

mBOC. 24. BC is a minor arc, so mBC Since A B is a diameter and AOC is a right angle, mAOB 180 and mAOC 90. mBOC mAOC ¬mAOB mBOC 90 ¬180 mBOC ¬90 ¬90 mBC mAOC. 25. AC is a minor arc, so mAC AOC is a right angle. ¬mAOC mAC ¬90 mAC mAOE. 26. AE is a minor arc, so mAE AOE and BOC are vertical angles. AOE ¬BOC mAOE ¬mBOC ¬mBOC mAE ¬90 mAE mEOB. 27. EB is a minor arc, so mEB EOB and AOC are vertical angles. EOB ¬AOC mEOB ¬mAOC ¬mAOC mEB ¬90 mEB 28. Since A B is a diameter, mAOB 180. mAOB mACB 180 mACB 29. Since BOD DOE EOF FOA, mBOD mDOE mEOF mFOA. Since mAOB 180, each of the four angles

33. WZV and UZY are vertical angles. WZV ¬UZY mWZV ¬mUZY ¬mUY mWV mWV ¬76 34. mWX mWZX 2x mWX From Exercise 32, x 26. 2(26) or 52 mWX 35. XZY ¬WZX mXZY ¬mWZX ¬mWX mXY mXY ¬52 mXY 36. mWUY 360 mWX mWUY 360 52 52 or 256 360 mWX mXY 37. mYVW mYVW 360 52 52 or 256 360 mXY 38. mXVY mXVY 360 52 or 308 360 mWX 39. mWUX mWUX 360 52 or 308 40. C d C (32) or 32 Let arc length. 10 0 360 ¬ 32 10 0 360 (32) ¬ 80 9 ¬

80 The length of DE is 9 units or about 27.93 units. 41. C d C 32 360 mDCE mDHE 360 90 or 270 mDHE Let arc length. 27 0 360 ¬ 32

18 0 measures 4 or 45.

AD is composed of adjacent arcs, DE, EF, and FA. mAD mDE mEF mFA mDOE mEOF mFOA mAD 45 45 45 or 135 mAD 30. CBF is composed of adjacent arcs, CB, BD, DE, and EF. mCB mBD mDE mEF mCBF mCBF mCOB mBOD mDOE

27 0 360 (32) ¬

mEOF 90 45 45 45 or 225 mCBF 360 mAC 31. mADC mADC 360 mAOC 360 90 or 270 mADC 32. Find the value of x. Since VY is a diameter, VUY is a semicircle. VUY and UY . VU is a is composed of adjacent arcs, VU mVZU. UY is a minor arc, minor arc, so mVU so mUY mUZY. mUY mVUY mVU mVZU mUZY 180 4x (2x 24) 180 6x 24 180 6x 156 x 26 . Use the value of x to find mUY mUY 2x 24 2(26) 24 mUY 52 24 or 76 mUY

Chapter 10

24 ¬ The length of DHE is 24 units or about 75.40 units. 360 mHCF 42. mHDF 360 125 or 235 mHDF Let arc length. 23 5 360 ¬ 32

23 5 360 (32) ¬ 188 9 ¬

188 The length of HDF is 9 units or about 65.62 units.

43. Let arc length. 45 36 0 ¬ 32 4 5 36 0 (32) ¬

4 ¬ The length of HD is 4 units or about 12.57 units. 44. Sample answer: 76%(360°) 273°, 16%(360°) 58°, 5%(360°) 18°, 3%(360°) 11°

350

45. The first category is a major arc, and the other three categories are minor arcs. 46. How many free files have you collected?

56. Sample answer: The hands of the clock form central angles. Answers should include the following. • The hands form acute, right, and obtuse angles. • Some times when the angles formed by the minute and hour hand are congruent are 1:00 and 11:00, 2:00 and 10:00, 3:00 and 9:00, 4:00 and 8:00, and 5:00 and 7:00. They also form congruent angles many other times of the day, such as 3:05 and 8:55. 57. B; C 2r or about 6.3r P 2 2w P 2(2r) 2r or 6r Since 6.3r 6r, the circumference of the circle is greater than the perimeter of the rectangle. 58. Rewrite 3:5:10 as 3x:5x:10x and use these measures for the measures of the central angles of the circle. 3x 5x 10x ¬360 18x ¬360 x ¬20 The measures of the angles are 3(20) or 60, 5(20) or 100, and 10(20) or 200.

101 to 500 16% 500 to 1000 5% 100 or less more than 1000 76% 3%

47. always 48. Sometimes; the central angle of a minor arc can be greater than 90°. 49. Never; the sum of the measures of the central angles of a circle is always 360. 50. always 51. Let m1 2x, then m2 3x and m3 4x. m1 m2 m3 ¬360 2x 3x 4x ¬360 9x ¬360 x ¬40 Therefore, m1 2(40) or 80, m2 3(40) or 120, and m3 4(40) or 160. 52. C d C (12) or 12 in. The measure of the angle from the minute hand to the hour hand at 2:00 is 60. Let arc length.

Page 535 Maintain Your Skills 59. d 2r d 2(10) or 20 C d C (20) or about 62.83

6 0 360 ¬ 12

60. r 1 2d

6 0 360 (12) ¬

r 1 2 (13) or 6.5 C d C (13) or about 40.84

2 ¬ The arc length is 2 in. or about 6.3 in. 53. C 2r C 2(12) or 24 Let arc length.

61.

27 0 360 ¬ 24

r 1 2d

27 0 360 (24) ¬

r 1 2 (28) or 14

18 ¬ The length of the arc is 18 ft or about 56.5 ft. 54. Given: BAC DAE C B D Prove: BC DE A

62.

d ¬24.00 r 1 2d

Proof:

1. 2. 3. 4.

BAC DAE mBAC mDAE mDE mBC BC DE

C ¬d 75.4 ¬d 75 .4 ¬d

E

Statements

C ¬d 28 ¬d 28 d or d 28

r 1 2 (24.00) or 12.00 2 63. magnitude (72) (45)2 or about 84.9

Reasons 1. 2. 3. 4.

45 direction tan1 72 or about 32

Given Def. of Def. of arc measure Def. of arcs

The magnitude is about 84.9 newtons and the direction is about 32° northeast. 12 10 64. 18 x ¬x 12x ¬10(18 x) 12x ¬180 10x 22x ¬180

55. No; the radii are not equal, so the proportional part of the circumferences would not be the same. Thus, the arcs would not be congruent.

2 x ¬8 1 1

351

Chapter 10

17 .3 26 .2 x ¬ 24.2 2

65.

75. 2x 2x x ¬180 5x ¬180 x ¬36 76. 3x ¬180 x ¬60

26.2(24.22) ¬17.3x 634.564 ¬17.3x 36.68 ¬x 66. Construct a line perpendicular to the line with the equation y 7 0 through point Q(6, 2). y

y70

10-3 Arcs and Chords Page 538 Geometry Activity: Congruent Chords and Distance 1. SU and S X are perpendicular bisectors of V T and W Y , respectively. 2. VT WY, SU SX 3. Sample answer: When the chords are congruent, they are equidistant from the center of the circle.

x

Q

The line y 7 0 is a horizontal line, so the line perpendicular to the given line is vertical. The desired distance is 2 7 or 9. The distance is 9 units. 67. First, write the equation of a line p perpendicular to both lines. The slope of each of the given lines is 1. So the slope of p is 1. Use the y-intercept of the first line, (0, 3). y y1 ¬m(x x1) y 3 ¬1(x 0) y 3 ¬x y ¬x 3 Next, find the point of intersection using the equations y x 3 and y x 4. x 3 ¬x 4 2x ¬7 x ¬7 2

Pages 539–540 Check for Understanding 1. Sample answer: An inscribed polygon has all vertices on the circle. A circumscribed circle means the circle is drawn around so that the polygon lies in its interior and all vertices lie on the circle. 2. Sample answer: 110 90 60 100

None of the sides are congruent. 3. Tokei; to bisect the chord, it must be a diameter and be perpendicular. 4. Given: X, U V W Y Prove: UV WY

1 y 7 2 4 or y 2

1 The point of intersection is 7 2 , 2 . Finally, find the distance between (0, 3) and 7

U

1

2, 2.

V

d ¬ (x2 x1)2 (y2 y1)2

X

7 1 2 0 2 3

¬

2

2

W

¬24.5 The distance between the lines is 24.5 units.

Y Proof: Because all radii are congruent, U X X V X W X Y . You are given that V U W Y , so UVX WYX, by SSS. Thus, UXV WXY by CPCTC. Since the central angles have the same measure, their intercepted arcs have the same measure and are therefore, congruent. Thus, UV WY. 1mAB . 5. O Y bisects AB, so mAY 2 1 mAY 2mAB 1(60) or 30 mAY

68. 90 57.5 ¬32.5 180 57.5 ¬122.5 The measures of the complement and supplement are 32.5 and 122.5, respectively. 69. If ABC has three sides, then ABC is a triangle. 70. Both are true. 71. x 42 since the triangle is isosceles. 72. x x 30 180 by the Angle Sum Theorem 2x ¬150 x ¬75 73. 40 40 x ¬180 x ¬180 80 or 100 74. x x 90 ¬180 2x ¬90 x ¬45 Chapter 10

2

6. O Y bisects A B , so AX 1 2 (AB). AX 1 2 (AB)

AX 1 2 (10) or 5

352

7. Draw radius O A . Radius O A is the hypotenuse of OXA. (OX)2 (AX)2 ¬(OA)2 (OX)2 52 ¬102 (OX)2 25 ¬100 (OX)2 ¬75 OX ¬ 75 or 53 8. A B and C E are equidistant from P, so A B C E . (CE), so CE 2(20) or 40. QE 1 2 B A C E , so AB 40. 9. (PE)2 ¬(PQ)2 (QE)2 (PE)2 ¬102 202 (PE)2 ¬100 400 (PE)2 ¬500 PE ¬10 5 or about 22.36 10. AB BC CA 36 0° Each arc measures 3 or 120°.

22. TZ bisects X Y , so XV VY. XY XV VY XY 5 5 or 10 mBC mCD mDE mEF 23. mAB mGH mHA 36 0 mFG or 45 8

mMJ mJK mKL 36 0 24. mLM 4 or 90 25. 2x x 2x x ¬360 6x ¬360 x ¬60 2x ¬120 mRQ 120; mNP 60 mNR mPQ 2 26. (LK) (FL)2 ¬(FK)2 (LK)2 82 ¬172 (LK)2 64 ¬289 (LK)2 ¬225 LK ¬15 27. F L bisects K M , so LK LM. KM KL LM KM 15 15 or 30 28. J G and K M are equidistant from the center, so J G K M . JG KM JG 30 29. F H bisects J G , so JH 1 2 (JG).

Pages 540–543 Practice and Apply 11. X Y bisects A B , so AM 1 2 (AB). AM 1 2 (AB) AM 1 2 (30) or 15

12. MB AM MB 15 13. X Z bisects C D , so CN 1 2 (CD).

JH 1 2 (JG)

CN 1 2 (CD) 1 CN 2(30) or 15

JH 1 2 (30) or 15

30. DF bisects B C , so FB CF. FB CF FB 8 31. D F bisects B C , so BC FB CF. BC FB CF BC 8 8 or 16 32. A B and B C are equidistant from the center, so A B B C . AB BC AB 16 33. (FD)2 (CF)2 ¬(DC)2 (FD)2 82 ¬102 (FD)2 64 ¬100 (FD)2 ¬36 FD ¬6 Since ED FD, ED 6. 34. Since X Y and S T are equidistant from the center, Y X S T . XY ST 4a 5 ¬5a 13 9a ¬18 a ¬2 ST 5a 13 ST 5(2) 13 ST 10 13 or 3 1 SQ 1 2 (ST) 2 (3) or 1.5 35. Since AC 20, then BC 1 2 (20) or 10. Since mACE 45 and mBDC ¬90, then mCBD 180 (90 45) or 45.

14. ND CN ND 15 mCZ . 15. X Z bisects CD, so mDZ mDZ mCZ 40 mDZ 1mCD . 16. X Z bisects CD, so mCZ 2 mCD 2mCZ 2(40) or 80 mCD mCD . 17. A B C D , so mAB mAB mCD 80 mAB 1mAB . 18. X Y bisects AB, so mYB 2 YB 1 mAB 2

YB 1 2 (80) or 40 19. (QR)2(PR)2 ¬(PQ)2 (QR)2 32 ¬52 (QR)2 9 ¬25 (QR)2 ¬16 QR ¬4 20. P R bisects Q S , so QS 2(QR). QS 2(QR) QS 2(4) or 8 21. TV 13 1 or 12 TX TW since both are radii. (XV)2 (TV)2 ¬(TX)2 (XV)2 (12)2 ¬(13)2 (XV)2 144 ¬169 (XV)2 ¬25 XV ¬5

353

Chapter 10

Therefore CD 5x. (CD)2 (BD)2 (BC)2 (5x)2 (5x)2 ¬102 25x2 25x2 ¬100 50x2 ¬100 x2 ¬2 x ¬ 2 or about 1.41 units 36a. Given 36b. All radii are congruent. 36c. Reflexive Property 36d. Definition of perpendicular lines 36e. ARP BRP 36f. CPCTC 36g. If central angles are congruent, intercepted arcs are congruent. 37. Given: O, O S R T , S R T V O U W , S O O V O W Prove: R T U W V U Proof: Statements 1. O T O W 2. O S R T, O V U W, S O O V 3. OST, OVW are right angles. 4. STO VWO 5. S T V W 6. ST VW 7. 2(ST) 2(VW) 8. OS bisects R T ; V O bisects U W . 9. RT 2(ST), UW 2(VW) 10. RT UW 11. R T U W

Statements 1. O, M N P Q , O N and O Q are radii, A O M N , B O P Q 2. O A bisects M N ; O B bisects P Q .

Chapter 10

4. Def. of segments

1 5. 1 2 MN 2 PQ

5. Mult. Prop.

39. Let x width of largest square. Use the Pythagorean Theorem. x2 x2 ¬42 2x2 ¬16 x2 ¬8 x ¬ 8 or about 2.82 The width is about 2.82 in. 40. C 34 m

B 30 m

34 m

D Let x distance from the center to the chord. Use the Pythagorean Theorem. x2 302 ¬342 x2 900 ¬1156 x2 ¬256 x ¬16 The chord is 16 m from the center of the circle. 41.

B 24 in.

30 in.

A 10. Substitution 11. Definition of segments

E

x

F

C

30 in.

D Since the diameter is 60 inches, the radius is 30 inches. Let x distance from the center to the chord. Use the Pythagorean Theorem. x2 242 ¬302 x2 576 ¬900 x2 ¬324 x ¬18 The chord is 18 in. from the center of the circle.

N Q

O

30 m

A xm

4. HL 5. CPCTC 6. Definition of segments 7. Multiplication Property 8. Radius to a chord bisects the chord. 9. Def. of seg. bisector

A

6. Substitution 7. Def. of segments 8. All radii of a circle are . 9. HL 10. CPCTC

9. AON BOQ 10. O A O B

3. Def. of lines

Proof:

4. MN PQ 6. AN BQ 7. A N B Q 8. O N OQ

1. All radii of a are . 2. Given

M

3. Def. of bisector

BQ 1 2 PQ

Reasons

N P Q 38. Given: O, M N O and O Q are radii. A O M N ; O B P Q Prove: O A O B

3. AN 1 2 MN;

B P

Reasons 1. Given

2. OA and O B are contained in radii. A radius to a chord bisects the chord.

354

42.

51. Sample answer: The grooves of a waffle iron are chords of the circle. The ones that pass horizontally and vertically through the center are diameters. Answers should include the following.

A 10 cm 48 cm

C x cm

B Let r the radius of the circle. Use the Pythagorean Theorem. 102 242 ¬r2 100 576 ¬r2 676 ¬r2 26 ¬r The radius is 26 cm.

11 yd

B

E C

D

• If you know the measure of the radius and the distance the chord is from the center, you can use the Pythagorean Theorem to find the length of half of the chord and then multiply by 2. • There are four grooves on either side of the diameter, so each groove is about 1 in. from the center. In the figure, EF 2 and EB 4 because the radius is half the diameter. Using the Pythagorean Theorem, you find that FB 3.464 in. so AB 6.93 in. Approximate lengths for other chords are 5.29 in. and 7.75 in., but exactly 8 in. for the diameter. 52. C; D B bisects A C and OA OC 53. Bridgeworth population in 2010 1.2(204,000) or 244,800 Sutterly population in 2010 1.2(216,000) or 259,200 In 2010, 259,200 244,800 or 14,400 more people will live in Sutterly than in Bridgeworth.

43.

16 yd

F

A

x yd

Since the diameter is 32 yards, the radius is 16 yards. Let x half of the length of the chord. Use the Pythagorean Theorem. x2 112 ¬162 x2 121 ¬256 x2 ¬135 x ¬ 135 The length of the chord is 2 135 or about 23.24 yd. 44. The line through the midpoint bisects the chord and is perpendicular to the chord, so the line is a diameter of the circle. Where two diameters meet would locate the center of the circle. 45. Let r be the radius of P. Draw radii to points D and E to create triangles. The length, DE, is r 3


54. KTR is a semicircle. mKTR mTR mKT mKT 180 mTSR 180 42 or 138 mKT 55. ERT is a semicircle. 180 mERT is by using mKT . 56. One way to find mKRT mKRT 360 mKT 360 138 or 222 mKRT 57. S U is a chord that is not a diameter. 58. MD is a radius and RI is a diameter. RI 2(MD) RI 2(7) or 14 59. All radii are congruent: R M , A M , D M , IM

r 3 1 and AB 2r; 2r 2.

46. Inscribed regular hexagon; the chords and the radii of the circle are congruent by construction. Thus, all triangles formed by these segments are equilateral triangles. That means each angle of the hexagon measures 120°, making all angles of the hexagon congruent and all sides congruent. 47. Inscribed equilateral triangle; the six arcs making up the circle are congruent because the chords intercepting them were congruent by construction. Each of the three chords drawn intercept two of the congruent chords. Thus, the three larger arcs are congruent. So, the three chords are congruent, making this an equilateral triangle. mCD 48. mAB 49. No; congruent arcs must be in the same circle or congruent circles, but these are in concentric circles. 50. A B C D ; in the smaller circle, O X O Y because they are radii. This means that in the larger circle, A B and C D are equidistant from the center, making them congruent chords.

60.

1x ¬120 2

61.

1x ¬25 2

x ¬240 x ¬50 62. 2x ¬1 2 (45 35) 2x ¬1 2 (80)

2x ¬40 x ¬20

355

Chapter 10

63. 3x ¬1 2 (120 60)

SC 1 2 CT

3x ¬1 2 (60)

SC 1 2 AC

3x ¬30 x ¬10

SC 1 2 (42) or 21 2 2 2 10. 1 2 x 5 ¬13

64. 45 ¬1 2 (4x 30) 1 45 ¬2(4x) 1 2 (30)

2 x4 25 ¬169 2 x4 ¬144

45 ¬2x 15 30 ¬2x 15 ¬x

x2 ¬576 x ¬24

65. 90 ¬1 2 (6x 3x) 90 ¬1 2 (9x)

10-4 Inscribed Angles

90 ¬4.5x 20 ¬x

Page 544 Geometry Activity: Measure of Inscribed Angles 1. See students’ work. 2(mXYZ) 2. mXZ 3. The measure of an inscribed angle is one-half the measure of its intercepted arc.

Page 543 Practice Quiz 1 1. B C , B D , and B A are radii. 2. BD and C B are radii, so BD CB. BD ¬CB 3x ¬7x 3 4x ¬3 x ¬3 4

Pages 548–549 Check for Understanding 1. Sample answer:

2BD AC is a diameter, so AC AC 2BD AC 2(3x) AC 6x AC 63 4 or 4.5 180. 3. ADC is a semicircle, so mADC mAD mADC mCD 180 mCBD mAD 180 85 or 95 mAD

D B A 2. The measures of an inscribed angle and a central angle for the same intercepted arc can be calculated using the measure of the arc. However, the measure of the central angle equals the measure of the arc, while the measure of the inscribed angle is half the measure of the arc. and mNP . mQP mMN 120 3. First find mQP mMQ 60 because the central angles and mNP are congruent vertical angles. 1 60 30 m1 1mNP

4. C 2r C 2(3) C 6 or about 18.8 in. 5. The degree measure of an arc connecting two 36 0 consecutive rungs is 40 or 9. 6. C 2r C 2(3) or 6 mCA mAD mCAD mCAD 180 mABD 180 150 or 330 mCAD Let arc length

2

2

1 m2 1 2 mQP 2 120 60 1 120 60 m3 1mMN 2 2 1 1 m4 2mNP 2 60 30 1 m5 1 2 MQ 2 60 30 1 m6 1 2 MN 2 120 60 1 m7 1 2 QP 2 120 60 1 m8 1 2 MQ 2 60 30

33 0 360 ¬ 6

33 0 360 (6) ¬

5.5 ¬ The length of CAD is 5.5 or about 17.3 units. 7. mCAM mNTM mCAM 28 8. mHMN 180 2(40) or 100 mHN mES mES mHMN 100 mES

4. Given: Quadrilateral ABCD is inscribed in P. mB mC 1 22(mDAB ) Prove: mCDA

B C A

P D

Proof: Given mC 1 2 (mB) means that mB 2(mC). Since mB 1 2 (mCDA)

9. CT AC

Chapter 10

C

356

and mC 1 2 (mDAB), the equation becomes ) 2 1(mDAB ) . Multiplying each side 1(mCDA

1 m1 1 2 mQR 2 120 60 1 45 22.5 m2 1mPS

by 2 results in mCDA 2(mDAB). 5. Angle PTS is a right angle because it intercepts a semicircle. m1 m2 mPTS ¬180 (6x 11) (9x 19) 90 ¬180 15x 120 ¬180 15x ¬60 x ¬4 Use the value of x to find the measures of 1 and 2. m1 6x 11 m2 ¬9x 19 6(4) 11 ¬9(4) 19 35 ¬55 mRS . Because PQ RS, mPQ m3 m4 because they are inscribed angles intercepting congruent arcs, PQ and RS. 4y 25 ¬3y 9 y ¬16 Use the value of y to find the measures of 3 and 4. m3 4y 25 m4 ¬3y 9 4(16) 25 ¬3(16) 9 39 ¬39 6. X

1 m3 1 2 mSR 2 75 37.5 1 m4 1 2 mPQ 2 120 60 1 45 22.5 m5 1mPS

2

2

2

2 2 1 m6 2mQR 1 2 120 60 1 1 m7 2mSR 2 75 37.5 1 m8 1 2 mPQ 2 120 60

2(mBDC) 9. mBC 2(25) or 50 mBC mBC mCD mAD ¬360 mAB 120 50 130 mAD ¬360 ¬60 mAD 1 m1 ¬2mAD ¬1 2 (60) or 30

m2 m1 or 30 m3 ¬1 mBC 2

¬1 2 (50) or 25

10. m1 m6 1 2 mXZ 1 2 (100) or 50 Y S T , XS SY, and m8 m11. Since X m1 m11 ¬90 50 m11 ¬90 m11 ¬40 m8 ¬40 m2 m8 ¬90 m2 40 ¬90 m2 ¬50 Since Z W S T , ZT TW, and m9 m10. m10 m6 ¬90 m10 50 ¬90 m10 ¬40 m9 ¬40 m9 m4 ¬90 40 m4 ¬90 m4 ¬50 XZW is a right angle because it intercepts a semicircle. m3 m4 ¬90 m3 50 ¬90 m3 ¬40 YXZ is a right angle because it intercepts a semicircle. m2 m5 ¬90 50 m5 ¬90 m5 ¬40 m5 m3 m7 ¬180 40 40 m7 ¬180 m7 ¬100

W V Y If a quadrilateral is inscribed in a circle, then its opposite angles are supplementary. V and X are opposite angles, so mV mX 180 mV 28 180 mV 152 W and Y are opposite angles, so mW mY 180 110 mY 180 mY 70 7. Since XZY is a semicircle, XZY is a right angle. So, the probability is 1.

Pages 549–551

2

Practice and Apply

and mQR . mPQ ¬mQR . 8. First find mPQ mPS mSR mQR mPQ ¬360 mPQ ¬360 45 75 mPQ ¬360 120 2mPQ ¬240 2mPQ ¬120 mPQ ¬120 mQR

357

Chapter 10

11. Given: AB DE, AC CE Prove: ABC EDC A

B

D

1

2

mAB 120, and mBC mAD mAB mAD mBC mCD mBC 120 120 mBC 2mBC mBC mCD 1 m4 2 mCD

E

C Proof: Statements 1. AB DE, AC CE mCE 2. mAB mDE, mAC , 3. 1mA A B 1mDE

1. Given 2. Def. of arcs

2

1 2 (60) or 30

3. Mult. Prop.

2 1mCE 2 4. mACB 1 2 mAB, mECD 1 2 mDE, , m2 1mCE m1 21mAC 2

m4 30 m4 m5 ¬90 30 m5 ¬90 m5 ¬60 m6 ¬60 15. KPR is a right angle because KPR is a semicircle. m2 ¬90 mR mK mP ¬180 mR mK 90 ¬180 mR mK ¬90

4. Inscribed Theorem

5. mACB mECD, m1 m2 6. ACB ECD, 1 2 B D E 7. A

5. Substitution 6. Def. of 7. arcs have chords. 8. AAS

8. ABC EDC 12. Given: P Prove: AXB CXD

1 2 (60) or 30 1 m7 mBC

Reasons

2 1mAC 2

1x 5 1x ¬90 3 2 5x ¬85 6

A C

x ¬102 m3 mR 1 3x 5 1 3 (102) 5 or 39

1 2 X

P

B

m1 mK 1 2x 1 2(102) or 51

D Proof: Statements

Reasons

1. P 2. A C

1. Given 2. Inscribed intercepting same arc are . 3. Vertical are . 4. AA Similarity

3. 1 2 4. AXB CXD

16. By the definition of a rhombus, Q P Q R R S S P . Therefore, PQ QR RS SP. 36 0 mSP or 90 4

mQRP 1 2 (mPQ) 1 2 (90) or 45

m2 since D E E C . m2 90 m2 45 is a right angle because ABC is a semicircle. m3 m4 180 45 90 m4 ¬180 m4 ¬45 1 m5 mCF

13. Inscribed angles that intercept the same arc are congruent. m1 ¬m2 x ¬2x 13 13 ¬x m1 x or 13 m2 13 14. m8 1mAB

17. m1 m1 m1 m3 m1

2

2

1 2 (120) or 60

1 2 (60) or 30

m7 is a right angle because AFC is a semicircle. m5 m6 m7 ¬180 30 m6 90 ¬180 m6 ¬60 2(m6) mAF 2(60) or 120

m2 m8 ¬90 m2 60 ¬90 m2 ¬30 so BC CD because BD AC m1 m2 m1 30 m3 m8 m3 60

Chapter 10

. ¬mCD ¬360 ¬360 ¬120 ¬60 ¬60

358

18.

23. mPSR 1 2 (mPQ mQR)

W

1 2 (72 72) or 72 mST mTP ) 1 24. mPQR 2(mRS

25. 26. 27.

R

Z

T If a quadrilateral is inscribed in a circle, then its opposite angles are supplementary. W and T are opposite angles, so mW mT ¬180 45 mT ¬180 mT ¬135 R and Z are opposite angles, so mR mZ ¬180 100 mZ ¬180 mZ ¬80

28.

1 2 (72 72 72) or 108 mPTS mPT mTS 72 72 or 144 mBZA or 104 mBA 360 (mBA mCB ) mADC 360 (104 94) or 162 mBDA 1mBA 2

1 2 (104) or 52 mCB 29. 2(mZAC) 180 ¬mBA 2(mZAC) 180 ¬104 94 2(mZAC) 180 ¬198 2(mZAC) ¬18 mZAC ¬9 2mABC 30. mAC 2(50) or 100 mDEF 1mDBF 2 1 2 (128) or 64

19.

A

40, then mPQS 360 40 or 320. If T 31. If mPS is located in PQS, then mPTS 1mPS

D

2

1 2 (40) or 20.

B

The probability that mPTS 20 is the same as the probability that T is contained in PQS,

C

Since ABCD is a trapezoid A D B C . A and B are consecutive interior angles so they are supplementary. mA mB ¬180 60 mB ¬180 mB ¬120 If a quadrilateral is inscribed in a circle, then its opposite angles are supplementary. A and C are opposite angles, so mA mC ¬180 60 mC ¬180 mC ¬120 B and D are opposite angles, so mB mD ¬180 120 mD ¬180 mD ¬60 20. Sample answer: P Q is a diagonal of PDQT and a diameter of the circle. 21. Sample answer: E F is a diameter of the circle and a diagonal and angle bisector of EDFG. 22. Since pentagon PQRST is equilateral, Q P Q R R S S T T P and PQ QR RS ST TP. 36 0 mQR or 72

32 0 8 360 or 9 .

110, then mPQR 360 110 or 250. 32. If mPSR If T is located in PQR, then mPTR 1mPSR 2

1 2 (110) or 55.

The probability that mPTR 55 is the same as the probability that T is contained in PQR, 25 0 25 360 or 36 .

33. No matter where T is selected, mSTQ 1 2 (180) or 90 because SPQ is a semicircle. Therefore, the probability that mSTQ 90 is 1. 360. 34. mPTQ can never equal 180 since mPQ Therefore, the propability that mPTQ 180 is 0.

5

359

Chapter 10

35. Given: T lies inside PRQ. R K is a diameter of T. Prove: mPRQ 1mPKQ

K

P

37. Given: inscribed MLN and CED, CD MN Prove: CED MLN

Q

2

N D

M O

C

T L E R

Proof: Statements

Proof:

Reasons

Statements

1. mPRQ mPRK 1. Addition Th. mKRQ mPK mKQ 2. mPKQ 2. Arc Addition Theorem 1mPK mPKQ 3. Multiplication Prop. 3. 1 2 2 1 mKQ

1. MLN and CED are 1. Given inscribed; CD MN ; mMN 2. Measure of an 2. mMLN 1 2 inscribed 1 mCED 2mCD half measure of intercepted arc. 3. Def. of arcs 3. mCD mMN 1mMN mCD 4. 1 4. Mult. Prop. 2 2

2

4. mPRK 1 2 mPK, mKRQ 1 2 mKQ

5. 1 2 mPKQ mPRK

4. The measure of an inscribed whose side is a diameter is half the measure of the intercepted arc (Case 1).

5. mCED mMLN 6. CED MLN

mKRQ 6. 1 2 mPKQ mPRQ

S

R Proof: Since PSR is a semicircle, PSR is also 180. PQR is an a semicircle and mPSR inscribed angle, and mPQR 1 2 (mPSR ) or 90,

Q

making PQR a right angle. 39. Given: quadrilateral ABCD inscribed in O Prove: A and C are supplementary. D B and D are supplementary.

T

R

Statements

Reasons 1. Angle Addition 1. mPRQ Theorem, Subtraction mKRQ mPRK Property mKQ mKP 2. mPQ 2. Arc Addition Theorem, Subtraction Property 1(mKQ mPQ 3. 1 3. Division Property 2 2 mKP)

5. mPRQ 21mKQ 1mKP

A B O C

Proof: By arc addition and the definitions of arc measure and the sum of central angles, mDAB 360. Since mC 1mDAB mDCB 2 , mC mA 1(mDCB and mA 1mDCB 2

2

), but mDCB mDAB 360, so mDAB mC mA 1 2 (360) or 180. This makes C

4. The measure of an inscribed whose side is a diameter is half the measure of the intercepted arc (Case 1).

and A supplementary. Because the sum of the measures of the interior angles of a quadrilateral is 360, mA mC mB mD 360. But mA mC 180, so mB mD 180, making them supplementary also.

5. Subst. (Steps 1, 4)

36 0 40. There are 8 congruent arcs, so each measures 8 or 45.

2

6. mPRQ 21(mKQ 6. Distributive ) Property mKP 1 7. mPRQ 2mPQ 7. Substitution (Steps 6, 3)

Chapter 10

Q

P C

6. Substitution (Steps 5, 1) 36. Given: T lies outside PRQ. K P R K is a diameter of T. Prove: mPRQ 1 2 mPQ

4. mPRK 1 2 mKP, mKRQ 1 2 mKQ

5. Substitution 6. Def. of

38. Given: PQR is a semicircle. Prove: PQR is a right angle.

5. Subst. (Steps 3, 4)

Proof:

Reasons

41. Isosceles right triangle because sides are congruent radii making it isosceles and AOC is a central angle for an arc of 90°, making it a right angle. 42. Square because each angle intercepts a semicircle, making them 90° angles. Each side is a chord of congruent arcs, so the chords are congruent.

360

51. C 2r C 2(12) or 24 Let length of QR.

43. Square because each angle intercepts a semicircle, making them 90° angles. Each side is a chord of congruent arcs, so the chords are congruent. 44. Use the properties of trapezoids and inscribed quadrilaterals to verify that ABCD is isosceles.

60 36 0 ¬¬ 24

60 36 0 (24) ¬

4 ¬ The length of QR is 4 units.

A B

52. C 2r C 2(16) or 32 Let length of QR.

D C mA mD 180 (same side interior angles 180) mA mC 180 (opposite angles of inscribed quadrilaterals 180) mA mD mA mC (Substitution) mD mC (Subtraction Property) D C (Def. of s) Trapezoid ABCD is isosceles because the base angles are congruent. 45. Sample answer: The socket is similar to an inscribed polygon because the vertices of the hexagon can be placed on a circle that is concentric with the outer circle of the socket. Answers should include the following. • An inscribed polygon is one in which all of its vertices are points on a circle. • The side of the regular hexagon inscribed in a 3 circle 3 4 inch wide is 8 inch.

90 36 0 ¬ 32

90 36 0 (32) ¬

53. 54. 55. 56.

57.

46. C; mAOB 2mACB, so the ratio is 1 : 2. 47. There are 18 even-numbered pages and 18 odd-numbered pages, so there are 18 6 18 7 or 234 articles.

Page 551

58.


48. Since AB 60, CD 30. Since DE 48, FD 24. (FD)2 (CF)2 ¬(CD)2 242 (CF)2 ¬302 (CF)2 ¬324 CF ¬18 49. Draw a line from C to E. Since AB 32, CE 16. Draw C E . Use the Pythagorean Theorem. (FE)2 (FC)2 (CE)2 (FE)2 112 ¬(16)2 FE2 ¬135 FE ¬ 135 FE ¬11.62 50. Since DE 60, FD 30. Use the Pythagorean Theorem. (FD)2 (FC)2 ¬(CD)2 302 162 ¬(CD)2 1156 ¬(CD)2 34 ¬CD Since AB 2(CD), AB 2(34) or 68.

8 ¬ The length of QR is 8 units. always sometimes sometimes Use the converse of the Pythagorean Theorem. a2 b2 ¬c2 42 52 ¬62 16 25 ¬36 41 ¬36 It is not a right triangle. Use the converse of the Pythagorean Theorem. a2 b2 ¬c2 32 82 ¬102 9 64 ¬100 73 ¬100 It is not a right triangle. Use the converse of the Pythagorean Theorem. a2 b2 ¬c2 282 452 ¬532 784 2025 ¬2809 2809 ¬2809 It is a right triangle.

10-5 Tangents Page 552 Geometry Software Investigation: Tangents and Radii 1. 2. 3. 4. 5.

WX is a radius. WX WY It doesn’t, unless Y and X coincide. X W X Y Sample answer: The shortest distance from the center of a circle to the tangent is the radius of the circle, which is perpendicular to the tangent.

Page 555 Check for Understanding 1a. Two; from any point outside the circle, you can draw only two tangents. 1b. None; a line containing a point inside the circle would intersect the circle in two points. A tangent can only intersect a circle in one point.

361

Chapter 10

10. Determine whether JGH is a right triangle. (JG)2 (GH)2 ¬(JH)2 52 122 ¬142 169 ¬196 Because the converse of the Pythagorean Theorem did not prove true in this case, JGH is not a right triangle. No; G H is not tangent to J. 11. Determine whether KLM is a right triangle. (KL)2 (LM)2 ¬(KM)2 2 102 62 ¬ 136 136 ¬136 Because the converse of the Pythagorean Theorem is true, KLM is a right triangle with right angle KLM and L M K L . Yes; K L is tangent to M. For Exercises 12–15, use the Pythagorean Theorem. 12. (NO)2 (NP)2 ¬(OP)2 62 x2 ¬102 36 x2 ¬100 x2 ¬64 x ¬8 2 2 13. (QR) (RS) ¬(QS)2 122 x2 ¬(12 8)2 144 x2 ¬400 x2 ¬256 x ¬16 14. (WU)2 (UV)2 ¬(WV)2 122 72 ¬x2 144 49 ¬x2 193 ¬x2 193 ¬x 15. (AC)2 (AB)2 ¬(BC)2 82 x2 ¬172 64 x2 ¬289 x2 ¬225 x ¬15 16. DE ¬DF x 2 ¬14 x ¬16 17. HJ ¬HN HJ ¬2 HK ¬HJ JK 5 ¬2 JK 3 ¬JK KL ¬JK KL ¬3 18. RS RQ 6 ST ¬TU 4 RT ¬RS ST x ¬6 4 or 10

1c. One; since a tangent intersects a circle in exactly one point, there is one tangent containing a point on the circle. 2. If the lines are tangent at the endpoints of a diameter, they are parallel and thus, not intersecting. 3. Sample answer: polygon circumscribed about a circle

polygon inscribed in a circle

4. Triangle MPO is a right triangle with hypotenuse O M . Use the Pythagorean Theorem. (MP)2 (PO)2 ¬(MO)2 162 x2 ¬202 256 x2 ¬400 x2 ¬144 x ¬12 5. If PRO is a right triangle, then R P is tangent to O. Use the converse of the Pythagorean Theorem. (PR)2 (PO)2 ¬(RO)2 52 122 ¬132 25 144 ¬169 169 ¬169 Yes, P R is tangent to O. 6. 4(3) 4x ¬32 4x ¬20 x ¬5 7. Each side of the square is 2(72) or 144 feet. The total length of fence is 4(144) or 576 feet.

Pages 556–558 Practice and Apply 8. Determine whether ABC is a right triangle. (AB)2 (BC)2 ¬(AC)2 162 302 ¬342 1156 ¬1156 Because the converse of the Pythagorean Theorem is true, ABC is a right triangle with right angle ABC and A B B C . Yes; B C is tangent to A. 9. Determine whether DEF is a right triangle. (EF)2 (DF)2 ¬(DE)2 32 42 ¬52 25 ¬25 Because the converse of the Pythagorean Theorem is true, DEF is a right triangle. Since DE is the longest side, F is the right angle. E is not a right angle, so DE is not perpendicular to EF. No; DE is not tangent to F. Chapter 10

19.

AC sin B ¬ B C 15 sin 30° ¬ x 15 x ¬ sin 30° or 30

362

20. (DG)2 (DE)2 ¬(EG)2 x2 162 ¬(12 x)2 x2 256 ¬144 24x x2 112 ¬24x

26.

4 2 3 ¬x

21. See students’ work. 22. Given: A B B A is a radius of A. Prove: is tangent to A.

B A

BE 4y ¬41 2 or 2

x

13

Statements 5

S

5 5

13

BD ¬12y 4 ¬121 2 4 or 2

AF ¬AD 10(z 4) ¬2z 10z 40 ¬2z 40 ¬8z 5 ¬z AF 10(z 4) AD ¬2z 10(5 4) or 10 ¬2(5) or 10 CE CF BE BD AF AD 6 6 2 2 10 10 or 36 The perimeter is 36 units. 27. Given: A B is tangent B to X at B. C A is tangent X to X at C. C Prove: A B A C Proof:

x O

CF ¬6(3 x) ¬6(3 2) or 6

1 ¬y 2

Proof: Assume is not tangent to A. Since touches A at B, it must touch the circle in another place. Call this point C. Then AB AC. But if A B , A B must be the shortest distance between A and . There is a contradiction. Therefore, is tangent to A. 23. Let r the radius of M. (PL)2 (ML)2 ¬(PM)2 102 r2 ¬(r 2)2 100 r2 ¬r2 4r 4 96 ¬4r 24 ¬r PL ML MN NP 10 24 24 2 or 60 The perimeter is 60 units. 24. R

5

CF ¬CE 6(3 x) ¬3x 18 6x ¬3x 18 ¬9x 2 ¬x CE 3x 3(2) or 6 BE ¬BD 4y ¬12y 4 4 ¬8y

A

Reasons

1. Given 1. AB is tangent to X at B, A C is tangent to X at C. 2. Draw B X , C X , and A X . 2. Through any two points, there is one line. 3. Line tangent to a B B X , A C C X 3. A circle is to the radius at the pt. of tangency. 4. ABX and ACX are 4. Def. of lines right angles. 5. All radii of a circle 5. B X C X are . 6. Reflexive Prop. 6. A X A X 7. HL 7. ABX ACX 8. CPCTC 8. A B A C

T

18

Use the Pythagorean Theorem to write an equation for RST. (x 5)2 182 ¬(x 13)2 2 x 10x 25 324 ¬x2 26x 169 180 ¬16x 11.25 ¬x 11.25 5 18 13 11.25 ¬58.5 The perimeter is 58.5 units. 25. d 5, r 2.5, GY EG 2.5. Since C B is a tangent, AEB is a right angle and GEB is a right triangle. Use the Pythagorean Theorem. (EG)2 (EB)2 ¬(GB)2 (2.5)2 (EB)2 ¬(2.5 2.5)2 6.25 (EB)2 ¬25 (EB)2 ¬18.75 EB ¬ 18.75 EB EC DC DA FA FB 6EB 6 18.75 or 15 3 The perimeter is 15 3 units.

28. Let a the radius of the roll of film, b the amount of film exposed, and c the distance from the center of the roll to the intake of the holding chamber. Since the diameter of the roll of film is 25, a 12.5. Use the Pythagorean Theorem. a2 b2 ¬c2 12.52 b2 ¬1002 156.25 b2 ¬10,000 b2 ¬9843.75 b ¬99 About 99 millimeters of film would be exposed.

363

Chapter 10

mAFC ¬1 2 mAC

29. A E and B F 30. A D and B C 31. 12; G

¬1 2 (90) or 45 BD ¬AC mBED ¬mAFC mBED ¬45 38. Connect L to J to form a right triangle. Use the Pythagorean Theorem. (LJ)2 ¬x2 52 102 ¬x2 52 100 ¬x2 25 75 ¬x2 5 3 ¬x or x 8.7 39. KB 5 2 or 3 Use the Pythagorean Theorem. 32 x2 ¬52 9 x2 ¬25 x2 ¬16 x ¬4 40. Connect O to A to form a right triangle; OA 8.

N

4

4

5Q

L 13

P

G , N L , and P L . Construct L Q G P , thus Draw P LQGN is a rectangle. GQ NL 4, so QP 5. Using the Pythagorean Theorem, (QP)2 (QL)2 (PL)2. So, QL 12. Since GN QL, GN 12. 32. Sample answer: Many of the field events have the athlete moving in a circular motion and releasing an object (discus, hammer, shot). The movement of the athlete models a circle and the path of the released object models a tangent. Answers should include the following. • The arm of the thrower, the handle, the wire, and hammer form the radius defining the circle when the hammer is spun around. The tangent is the path of the hammer when it is released. • The distance the hammer was from the athlete was about 70.68 meters. 33. A

x

R x

S

y

y

19

x

Let x 1 2 AP. Use the Pythagorean Theorem. 42 x2 ¬82 16 x2 ¬64 x2 ¬48 x ¬4 3 AP 24 3 or 8 3 13.9 41. Sample answer: Given: ABCD is a rectangle. E is the midpoint of A B .

D(0, b)

B y 6

P

A(0, 0)

Q 14

902 912 922 992 9470

B(2a, 0) x

42. x 3 1 2 [(4x 6) 10] 1 x 3 2(4x 4)

49,7 00 470 1470 2470 9470 100 or 497 100

35. A D and B C 36. A E and B F or A C and B D

x 3 2x 2 5x 43. 2x 5 1 2 [(3x 16) 20] 1 2x 5 2(3x 4)

Page 558 Maintain Your Skills ¬mFA mAC mFAC 180 ¬90 mAC 90 ¬mAC

Chapter 10

E(a, 0)

Prove: CED is isosceles. Proof: Let the coordinates of E be (a, 0). Since E is the midpoint and is halfway between A and B, the coordinates of B would be (2a, 0). Let the coordinates of D be (0, b), so the coordinates of C would be (2a, b) because it is on the same horizontal as D and the same vertical as B. ED (a 0 )2 (0 b)2 2 2 a b 2 EC (a 2a) (0 b )2 2 2 a b Since ED EC, E D E C . DEC has two congruent sides, so it is isosceles.

y

C PB RB ¬19 x CP CQ ¬14 y PB CP ¬6 (19 x) (14 y) ¬6 33 x y ¬6 27 ¬x y AD ¬27 34. B; 2 12 22 92 470 102 112 122 192 1470

37.

C(2a, b)

D

2x 5 3 2x 2 1x ¬3 2

x ¬6

364

44. 2x 4 1 2 [(x 20) 10] 1 2x 4 2(x 10)

10-6 Secants, Tangents, and Angle Measures

2x 4 1 2x 5 3 x ¬1 2


x ¬2 3 1 45. x 3 2[(4x 10) 45]

1. Sample answer: A tangent intersects the circle in only one point and no part of the tangent is in the interior of the circle. A secant intersects the circle in two points and some of its points do lie in the interior of the circle. 2. Sample answer: A T

x 3 1 2 (4x 35) 35 x 3 2x 2 4 1 2 ¬x or x 20.5

Page 560 Geometry Activity: Inscribed and Circumscribed Triangles

C

1. 2. 3. 4.

See students’ work. See students’ work. See students’ work. The incenter is equidistant from each side. The perpendicular to one side should be the same length as it is to the other two sides. 5. The incenter is equidistant from all the sides. The radius of the circle is perpendicular to the tangent sides and all radii are congruent, matching the distance from the incenter to the sides. 6. The circumcenter is equidistant from all three vertices, so the distance from the circumcenter to one vertex is the same as the distance to each of the others. 7. The circumcenter is equidistant from the vertices and all of the vertices must lie on the circle. So, this distance is the radius of the circle containing the vertices.

Angle TAC is a right angle; There are several reasons: (1) If the point of tangency is the endpoint of a diameter, then the tangent is perpendicular to the diameter at that point. (2) The arc intercepted by the secant (diameter) and the tangent is a semicircle. Thus the measure of the angle is half of 180 or 90. 3. m1 180 1 2 (38 46) 1 ¬180 2(84)

¬180 42 or 138 4. m2 1 2 (360 100) ¬1 2 (260) or 130 5. x 1 2 [84 (180 84 52)] ¬1 2 (84 44) ¬1 2 (40) or 20

36 0 8. 6 60

9. r

30

3

r

6. x 1 2 [128 (360 148 128)] 1 ¬2(128 84) ¬1 2 (44) or 22 7. 55 ¬1 2 [x (360 x)] 1 55 ¬2(2x 360)

60

55 ¬x 180 235 ¬x

Suppose all six radii are drawn. Each central angle measures 60°. Thus, six 30°-60°-90° triangles are formed. Each triangle has a side which is a radius r units long. Using 30°-60°-90° side ratios, the segment tangent to the circle has length r 3, making each side of the 3. If all three sides circumscribed triangle 2r have the same measure, then the triangle is equilateral. 10. The incenter is the point from which you can construct a circle “in” the triangle. Circum means around. So the circumcenter is the point from which you can construct a circle “around” the triangle.

8. mCAS ¬1 2 mSA ¬1 2 (46) or 23 9. mSAK 2mSLK 2(78) or 156 mSA mAK mSAK 156 46 or 110 mQAK 1mAK 2

1 2 (110) or 55

365

Chapter 10

25 ¬1 2 (90 5x) 50 ¬90 5x 40 ¬5x 8 ¬x 24. 360 (160 34 106) ¬60

10. Since S A L K , ASL and SLK are supplementary consecutive interior angles. So mASL 180 78 or 102 and mAKL 2(mASL) 2(102) or 204. mAK mKL mAKL 204 ¬110 mKL (See Exercise 9.) 94 ¬mKL mSL ¬360 11. mSA mAK mKL 46 110 94 mSL¬360 ¬360 250 mSL ¬110 mSL

23.

Pages 564–567

26. x ¬1 2 (10x 40)

x ¬1 2 (60 34) x ¬1 2 (26) or 13 25. x ¬1 2 (7x 20)

2x ¬7x 20 20 ¬5x 4 ¬x

Practice and Apply

12. m3 ¬1 2 (100 120) 1 2(220) or 110 13. m4 1 2 (45 75) 1 2(120) or 60 14. m5 1 2 [360 (110 150)] 1 ¬2(360 260) ¬1 2 (100) or 50

x ¬5x 20 20 ¬4x 5 ¬x 27. x 2.5 ¬1 2 [(4x 5) 50]

2x 5 ¬4x 45 50 ¬2x 25 ¬x 28. 90 60 ¬30 30 ¬1 2 (105 5x) 60 ¬105 5x 5x ¬45 x ¬9

15. 5a 3a 6a 4a ¬360 18a ¬360 a ¬20 (5a 6a) m6 1 2

29. 50 ¬1 2 [(360 x) x] 100 ¬360 2x 2x ¬260 x ¬130

¬1 2 (11a) ¬1 2 (11 20)

30. 30 ¬1 2 [x (360 x)] 60 ¬2x 360 420 ¬2x 210 ¬x

¬1 2 (220) or 110 16. m7 1 2 (196) or 98 17. m8 1 2 (180) or 90

31. 3x 1 2 [(4x 50) 30] 1 3x 2(4x 20)

18. m9 1 2 (360 120) 1 2 (240) or 120

3x 2x 10 x ¬10

19. m10 ¬1 2 [360 (100 160)] 1 ¬2(360 260)

2 2 32. 40 ¬1 2 [(x 12x) (x 2x)] 1 40 ¬2(10x)

¬1 2 (100) or 50 20. 65 ¬1 2 (mAC 72) 130 ¬mAC 72 58 ¬mAC

40 ¬5x 8 ¬x 33. mC 1 2 (116 38) 1 2(78) or 39 mBH ) mC ¬1(mBAH

21. x 1 2 (90 30) 1 ¬2(60) or 30

2 1 39 ¬ 2 [(360 mBH) mBH] 39 ¬1 2 (360 2mBH)

22. x ¬1 2 [20 (180 20 150)] 1 ¬2(20 10) ¬1 2 (10) or 5

Chapter 10

39 ¬180 mBH mBH ¬141

366

2mEFB 34. mBE 2(30) or 60 mFGE 180 52 or 128

DG is a tangent to the circle. DF is a 40b. Given: secant to the circle. Prove: mFDG 1 2 mFG mGE F

mFGE mEFB mGEF ¬180 128 30 mGEF ¬180 mGEF ¬22 2mGEF mCF 2(22) or 44 360 (mAB mBE mFE mCF ) mAC 360 (108 60 118 44) 360 330 or 30 44 (See Exercise 34.) 35. mCF 36. mEDB ¬1 2 (mBE mAC)

E D G Proof: Statements

¬1 2 (30) or 15

37. mAMB ¬23.5

mAMB ¬1 2 (mBC mAB) 23.5 ¬1 2 (mBC 71) 71 47 ¬mBC 118 ¬mBC 38. mABC mAB mBC mABC 71 118 or 189

3. mFGH mDFG mFDG 1mGE 4. 1mFG 2

mFDG 6. 1 2 mFG mGE

3. Exterior Theorem 4. Substitution 5. Subtraction Prop. 6. Distributive Prop.

mFDG

11 8 360 314.2 103

HI and HJ are tangents to the circle. 40c. Given: Prove: mIHJ 1 2 (mIXJ mIJ)

You would walk about 103 ft. and AT are secants to the circle. 40a. Given: AC mBR ) Prove: mCAT 1(mCT 2

I

X

B T

R

H J Proof: Statements

Proof: Statements

Reasons

1. AC and AT are secants to the circle. 2. mCRT 1 2 mCT, mACR 1mBR

1. Given

2

3. mCRT mACR mCAT 1mBR 4. 1mCT 2

2

mFDG 1 5. 1 2 mFG 2 mGE

No, its measure is 189, not 180. 39. C d C (100) 314.2 feet

A

Reasons

is a tangent to the 1. Given 1. DG is a secant circle. DF to the circle. 2. The meas. of an 2. mDFG 1 2 mGE, inscribed 1 2 mFG mFGH 1 2 the meas. of its intercepted arc.

¬1 2 (60 30)

C

H

2

mCAT 1 5. 1 2 mCT 2 mBR mCAT 6. 1 2 mCT mBR

K Reasons

1. Given 1. HI and HJ are tangents to the circle. 2. The measure of an 2. mIJK 1 2 mIXJ, 1 1 inscribed 2 mHIJ 2mIJ

2. The meas. of an inscribed 1 2 the meas. of its intercepted arc. 3. Exterior Theorem

4. Substitution

3. mIJK mHIJ mIHJ 1mIJ 4. 1mIXJ

5. Subtraction Prop.

mIHJ 1 5. 1 2 mIXJ 2 mIJ

2

2

mIHJ 6. 1 2 (mIXJ mIJ) mIHJ

6. Distributive Prop.

mCAT

367

the measure of its intercepted arc. 3. Ext. Th. 4. Substitution 5. Subtr. Prop. 6. Distrib. Prop.

Chapter 10

1mCA by substitution. 1mDC 2 2 mDAC 1 2 mDC since DAC is inscribed, so 1 substitution yields 1 2 mDC mCAB 2 mDC . By Subtraction Prop., mCAB 1mCA . 21mCA 2

41. The diagonals of a rhombus are perpendicular. Let x side length of rhombus. 52 122 ¬x2 25 144 ¬x2 169 ¬x2 13 ¬x y

is a tangent to O. 43b. Given: AB is a secant to O. CAB is obtuse. AC Prove: mCAB 1 2 mCDA

r

5

D 12

5

C

x

E

Let r radius of inscribed circle. The radius forms two right triangles. One triangle has a hypotenuse of 5. Let y measure of the portion of the side of the rhombus that is a leg of this triangle. The second right triangle has a hypotenuse of length 12. Its second leg has measure 13 y. Use the Pythagorean Theorem to write an equation for each triangle. r2 (13 y)2 122 r2 y2 ¬52 r2 ¬25 y2 Substituting for r2, 25 y2 (13 y)2 ¬144 25 y2 169 26y y2 ¬144 194 26y ¬144 26y ¬50 y ¬1.9 r2 25 1.92 r2 21.39 r 4.6 The radius of the inscribed circle is approximately 4.6 cm. 42. Let x measure of intercepted arc. 86.5 ¬1 2 [(360 x) x] 173 ¬360 2x 2x ¬187 x ¬93.5 43a. Given: AB is a tangent to O. is a secant to O. CAB is acute. AC Prove: mCAB 1mCA

the Transitive Prop., mCAB mCAE , so by Subtraction Prop., mCAE 1mCDA 2

mCAB 1 2 mCDA. 44. Let x the measure of the angle of view. 360 54 306 x 1 2 (306 54) 1 x 2(252) or 126

, m1 1mRQ so 45. 3, 1, 2; m3 mRQ 2 mTP ) m3 m1, m2 1(mRQ 2 1mTP , which is less than 1mRQ , 1mRQ 2 2 2

so m2 m1. 46. Sample answer: Each raindrop refracts light from the sun and sends the beam to Earth. The raindrop is actually spherical, but the angle of the light is an inscribed angle from the bent rays. Answers should include the following. • C is an inscribed angle and F is a secantsecant angle. • The measure of F can be calculated by finding and the the positive difference between mBD measure of the small intercepted arc containing point C. 47. A; let x the measure of the common intercepted arc of A and B.

2

C B

mA ¬1 2 (x 15)

Proof: DAB is a right with measure 90, and DCA is a semicircle with measure 180, since if a line is tangent to a , it is to the radius at the point of tangency. Since CAB is acute, C is in the interior of DAB, so by the Angle and Arc Addition Postulates, mDAB mDAC mDC mCA . By mCAB and mDCA substitution, 90 mDAC mCAB and 1 180 mDC mCA. So, 90 1 2 mDC 2 mCA

10 ¬1 2 (x 15) 20 ¬x 15 35 ¬x mB 1 2 (95 35) 1 ¬2(60) or 30

48. C; the set of data can be represented by the linear equation y 1 2 x 1.

by Division Prop., and mDAC mCAB Chapter 10

B

2 1mCDA 180 by Division Prop., and 1mCA 2 2 180 by substitution. By 1mCAE 1mCDA 2 2

D

A

A

Proof: CAB andCAE form a linear pair, so mCAB mCAE 180. Since CAB is obtuse, CAE is acute and Case 1 applies, so . mCA mCDA 360, so mCAE 1mCA

}

O

O

368

x2 6x 40 ¬0 (x 4)(x 10) ¬0 x 4 0 or x 10 ¬0 x ¬4 x 10 58. 2x2 7x 30 ¬0 (2x 5)(x 6) 0 2x 5 0 or x 6 0


57.

49. The tangent forms a right angle with the radius. Use the Pythagorean Theorem. (2x)2 242 ¬(16 24)2 4x2 576 ¬1600 4x2 ¬1024 x2 ¬256 x ¬16 50. Both tangents to the circle on the left have the same measure. Both tangents to the circle on the right have the same measure. Both tangents to the circle in the middle have the same measure. Because the left tangent to the middle circle is also tangent to the left circle and the right tangent to the middle circle is also tangent to the right circle, the tangents to the left and right circles have the same measure. 12x 10 ¬74 4x 16x ¬64 x ¬4 51. EGN is an inscribed angle. mEGN 1mEN

x 5 2 1 x 22

59. 3x2 24x 45 ¬0 3(x2 8x 15) 0 3(x 3)(x 5) ¬0 x 3 0 or x 5 0 x3 x5


36 0 1. Each central angle has a measure of 8 or 45. Therefore, the remaining 2 angles in each triangle 180 45 each measure or 67.5. 2

2. Inscribed angles of the same arc are congruent. m1 m2 1 2 (68) or 34 3. x 2(6) or 12

2 1 2 (66) or 33

¬mGE mEN 52. mGEN 180 ¬mGE 66 114 ¬mGE mGME 1mGE

4. x 1 2 (60 34) 1 2 (26) or 13

5. 360 129 231

2 1 2 (114) or 57

x 1 2 (231) or 115.5

89 53. mGM GNM is an inscribed angle that intercepts GM. 1 mGNM (mGM)

10-7 Special Segments in a Circle

2 1 2 (89) or 44.5 vertical rise 54. slope horizontal run 1 slope 12 1 The slope is 1 2.

Page 569 Geometry Activity: Intersecting Chords 1. PTS RTQ (vertical are ); P R ( intercepting same arc are ); S Q ( intercepting same arc are ) 2. They are similar by AA Similarity.

55. 30 feet 30 12 or 360 in. Let x the height of the ramp. (12x)2 x2 3602 145x2 ¬129,600 x2 ¬893.8 x ¬30 The ramp is about 30 in. high. 56. Given: A C B F Prove: AB CF

A

B C

x 6

PT ST 3. RT TQ or PT TQ RT ST

Pages 571–572 Check for Understanding 1. Sample answer: The product equation for secant segments equates the product of exterior segment measure and the whole segment measure for each secant. In the case of secant-tangent, the product involving the tangent segment becomes (measure of tangent segment)2 because the exterior segment and the whole segment are the same segment. 2. Latisha; the length of the tangent segment squared equals the product of the exterior secant segment and the entire secant, not the interior secant segment.

F

Proof: By definition of congruent segments, AC BF. Using the Segment Addition Postulate, we know that AC AB BC and BF BC CF. Since AC BF, this means that AB BC BC CF. If BC is subtracted from each side of this equation, the result is AB CF.

369

Chapter 10

3. Sample answer: B

A 12.

C D 4. 9x ¬3(6) 9x ¬18 x ¬2 5. 312 ¬20(20 x) 961 ¬400 20x 561 ¬20x 28.1 ¬x 6. x(10 x) ¬3(3 5) 10x x2 ¬24 2 x 10x 24 ¬0 (x 2)(x 12) ¬0 x 2 ¬0 or x 12 ¬0 x ¬2 x ¬12 Since x represents a length, it must be positive. Reject the negative value. So x 2. 7. Draw a model using a circle. Let x represent the unknown measure of the segment of diameter AB. Use the products of the lengths of the intersecting chords to find the length of the diameter. A

13.

14.

15.

16.

3

D

E 3.5

3.5

17.

C

x B AE EB ¬DE EC 3x ¬3.5 3.5 x ¬4.08 AB ¬AE EB AB ¬3 4.08 or 7.08 7.08 The radius of the circle is about 2 or 3.54. The ratio of the arch width to the radius of the circle is about 7:3.54.

Pages 572–574

18.

19.

Practice and Apply

8. 2x ¬4(5) 2x ¬20 x ¬10 9. 6 6 x 9 36 ¬9x 4 ¬x 10. 7 2 ¬3 x 14 ¬3x 1 4 3 ¬x or x 4.7 11. x(x 8) ¬5 4 x2 8x ¬20 x2 8x 20 ¬0 (x 2)(x 10) 0

Chapter 10

x 2 ¬0 or x 10 ¬0 x ¬2 x ¬10 Disregard the negative value. x ¬2 x2 ¬3(9 3) x2 ¬36 x ¬6 42 ¬2(x 2) 16 2x 4 12 2x 6 ¬x 162 ¬x(x x 16) 256 ¬x(2x 16) 256 ¬2x2 16x 0 ¬2x2 16x 256 0 ¬x2 8x 128 0 ¬(x 16)(x 8) 0 ¬x 16 or 0 ¬x 8 16 ¬x 8 ¬x Since the length of a segment cannot be negative, reject x ¬16. So x ¬8. (9.8)2 7.1(2x 7.1) 96.04 14.2x 50.41 45.63 14.2x 3.2 x 4(4 2) 3(3 x) 24 ¬3(3 x) 8 ¬3 x 5 ¬x x(5 x) ¬3(3 9) 5x x2 ¬36 2 x 5x 36 ¬0 (x 4)(x 9) ¬0 x 4 ¬0 or x 9 ¬0 x ¬4 x ¬9 Disregard the negative value. x ¬4 x(x 5 x) 5(5 5 x) x(5 2x) ¬5(10 x) 5x 2x2 ¬50 5x 2x2 ¬50 x2 ¬25 x ¬5 x(x 3x) ¬8(8 x 2) x(4x) ¬8(10 x) 4x2 ¬80 8x 2 4x 8x 80 ¬0 4(x 2x 20) ¬0 2 (2) (2) 4(1)(20 ) x 2(1) 2 84 x 2 x 5.6 or x 3.6 Disregard the negative value. So x 5.6.

370

20. Let r the radius of the circle.

2x(2x 24) ¬y(y 12.25) 2(3)(2 3 24) ¬y2 12.25y 180 ¬y2 12.25y 0 ¬y2 12.25y 180 2 4(1)(1 12.25 (12.25 ) 80) y ¬

2 4.25

2

2(1)

x

y ¬8.6 or y ¬20.9 Disregard the negative value. So y ¬8.6. 27. 3(3 x) ¬4(4 9) 9 3x ¬52 3x ¬43 x ¬14.3 28. 102 ¬y(6 y) 100 ¬6y y2 0 ¬y2 6y 100 2 4(1)(1 6 6 00) y ¬

Let x represent the unknown measure of the segment of the diameter. Use the products of the lengths of the intersecting chords to find the length of the diameter. 4.25x ¬2 2 x ¬0.94 d ¬4.25 0.94 or 5.19 mm

2(1)

1 r ¬1 2 d ¬ 2 (5.19) or 2.6 mm

21. Given: WY and Z X intersect at T. Prove: WT TY ZT TX

y ¬7.4 or y ¬13.4 Disregard the negative value. So y ¬7.4. 29. Let r the radius of the circle. Draw a model using a circle. Let x represent the unknown measure of the segment of the diameter. Use the products of the lengths of the intersecting chords to find the diameter. 60x ¬100 100 x ¬166.6

W X T Y

Proof:

Z

Statements

Reasons

a. W Z, X Y

a. Inscribed angles that intercept the same arc are congruent. b. AA Similarity c. Definition of similar triangles

b. WXT ZYT W T TX c. ZT TY

60 100

100

x

d. WT TY ZT TX d. Cross products 22. 4(9) ¬(8 x)(8 x) 36 ¬64 x2 x2 ¬28 x ¬5.3 23. 2(5 3) ¬y2 16 ¬y2 4 ¬y 2 24. 12 ¬6(6 y 3) 144 ¬54 6y 90 ¬6y 15 ¬y

60 or 226.6 cm d ¬166.6 1 r ¬1 2 d ¬ 2 (226.6) or 113.3 cm The radius is 113.3 cm. 30. Given: EC and E B are secant segments. Prove: EA EC ED EB B

D

C

A

E

2x ¬3y 2x ¬3(15) 2x ¬45 x ¬22.5 25. 10(10 8) ¬9(9 x) 180 ¬81 9x 99 ¬9x 11 ¬x 26. 92 ¬x(x 24) 81 ¬x2 24x 0 ¬x2 24x 81 0 ¬(x 3)(x 27) 0 ¬x 3 or 0 ¬x 27 3 ¬x 27 ¬x Disregard the negative value. So x ¬3.

Proof: Statements 1. EC and E B are secant segments. 2. DEC AEB 3. ECD EBA

4. ABE DCE E A EB 5. ED EC

6. EA EC ED EB

371

Reasons 1. Given 2. They name the same angle. (Reflexive Prop.) 3. Inscribed that intercept the same arc are . 4. AA Similarity 5. Definition of similar triangles 6. Cross Products

Chapter 10

31. Given: tangent R S and secant US Prove: (RS)2 US TS

Page 574


36. 360 102 258

R

m1 1 2 (258) or 129

S

37. m2 1 2 (85 230) 1 2 (315) or 157.5

T

38. m3 1 2 (28 2 12)

U

Proof: Statements 1. tangent R S and secant U S 2. mRUT 1 2 mRT

3. mSRT 1 2 mRT

4. mRUT mSRT 5. SUR SRT 6. S S 7. SUR SRT TS RS 8. U S RS

9. (RS)2 US TS

1 2 (52) or 26

Reasons

39. x 7 40. Connect the center with the point of tangency, forming a right triangle. Use the Pythagorean Theorem. (12 x)2 ¬122 162 144 24x x2 ¬144 256 x2 24x 256 ¬0 (x 8)(x 32) ¬0 x 8 ¬0 or x 32 ¬0 x ¬8 x ¬32 Disregard the negative value. So x ¬8. 41. x 36 42. tan 67° ¬5x 5 tan 67° ¬x 12 ¬x The distance across the stream is about 12 feet. 43. No two sides are congruent, and one angle is greater than 90. The triangle is scalene and obtuse. 44. Two sides are congruent and one angle is a right angle. The triangle is isosceles and right. 45. All of the sides are congruent and all three angles congruent. The triangle is equilateral, acute or equiangular. 46. d (x x1)2 (y2 y1)2 2

1. Given 2. The measure of an inscribed angle equals half the measure of its intercepted arc. 3. The measure of an angle formed by a secant and a tangent equals half the measure of its intercepted arc. 4. Substitution 5. Definition of congruent angles 6. Reflexive Prop. 7. AA Similarity 8. Definition of similar triangles 9. Cross Products

ZY ¬XY (WX)2 ¬XY XZ (WX)2 ¬XY(XY ZY) (WX)2 XY(2XY) (WX)2 ¬2(XY)2 WX ¬ 2(XY)2 WX ¬ 2 XY 33. Sample answer: The product of the parts of one intersecting chord equals the product of the parts of the other chord. Answers should include the following. • A F, F D, E F, F B • AF FD EF FB 34. D; x2 ¬20 x x2 x 20 ¬0 (x 4)(x 5) ¬0 x 4 0 or x 5 ¬0 x ¬4 x ¬5 32.

d (10 (2))2 (1 2 7)2 d 144 25 d 169 or 13 47. d (x x1)2 (y2 y1)2 2 2 (4 d (3 1) 7)2 d 4 9 or 13

48. d (x x1)2 (y2 y1)2 2 d (15 9)2 (2 (4))2 d 36 4 or 40

35. C; let x time working together. x x 1 5 3 0 ¬1

x x 30 1 5 3 0 ¬30(1) 2x x ¬30 3x ¬30 x ¬10 It will take them 10 minutes working together.

Chapter 10

372

The center is at (3, 0), and the radius is 4.

Equations of Circles Pages 577–578

y


1. Sample answer:

(3, 0) x

O

y

x

O

8. Explore: You are given three points that lie on a circle. Plan: Graph NMQ. Construct perpendicular bisectors of two sides to locate the center. Find the length of the radius. Use the center and radius to write an equation.

2. A circle is the locus of all points in a plane (coordinate plane) a given distance (the radius) from a given point (the center). The equation of a circle is written from knowing the location of the given point and the radius. 3. (x h)2 (y k)2 ¬r2 [x (3)]2 (y 5)2 ¬102 (x 3)2 (y 5)2 ¬100 4. (x h)2 (y k)2 ¬r2 (x 0)2 (y 0)2 ¬( 7)2 x2 y2 ¬7 5. First find the length of the diameter and radius. d (x x1)2 (y2 y1)2 2

y

Q(2, 2) x

O

M(2, 2) N(2, 2) Solve: The center is at (0, 0). r (0 2 )2 [0 (2 )]2 or 8 Write an equation. (x 0)2 (y 0)2 (8 )2 x2 y2 8

d (6 2)2 (15 7)2 d 64 64 or 82 2 8 r or 42

y

2

The center is the midpoint of the diameter:

Q (2, 2)

2 15 7 , C 2(6) or C(2, 11) 2

O

(x h)2 (y k)2 ¬r2 [x (2)]2 (y 11)2 ¬(42 )2 2 2 (x 2) (y 11) ¬32 6. (x 5)2 (y 2)2 9 (x h)2 ¬(x 5)2 (y k)2 ¬(y 2)2 x h ¬x 5 y k ¬y 2 h ¬5 k ¬2 h ¬5 k ¬2 r2 9, so r 3 The center is at (5, 2), and the radius is 3.

x

M

N(2, 2)

( 2, 2)

Examine: Verify the location of the center by finding the equations of the two bisectors and solving a system of equations. bisector of M N : M N is horizontal so its bisector is vertical and goes through the midpoint of M N : (0, 2). Its equation is x 0. bisector of Q N : Q N is vertical so its bisector is horizontal and goes through the midpoint of N Q : (2, 0). Its equation is y 0. The intersection of x 0 and y 0 is the point (0, 0). So the center is correct. 9. The center is at (0, 0) and the radius is 4(10) or 40. (x h)2 (y k)2 ¬r2 (x 0)2 (y 0)2 ¬402 x2 y2 ¬1600

y

( 5, 2)

O x

7. (x 3)2 y2 16 Write the equation in standard form. (x 3)2 (y 0)2 42

373

Chapter 10

22. If d 12, r 6. The center is at (0 18, 0 7) or (18, 7). (x h)2 (y k)2 ¬r2 [x (18)]2 [y (7)]2 ¬62 (x 18)2 (y 7)2 ¬36 23. Sketch a drawing of the two tangent lines.

Pages 578–580 Practice and Apply 10. (x (y (x 0)2 (y 0)2 ¬32 x2 y2 ¬9 11. (x h)2 (y k)2 ¬r2 [x (2)]2 [y (8)]2 ¬52 (x 2)2 (y 8)2 ¬25 12. (x h)2 (y k)2 ¬r2 (x 1)2 [y (4)]2 ¬( 17)2 2 2 (x 1) (y 4) ¬17 13. If d 12, r 6. (x h)2 (y k)2 ¬r2 (x 0)2 (y 0)2 ¬62 x2 y2 ¬36 14. (x h)2 (y k)2 ¬r2 (x 5)2 (y 10)2 ¬72 (x 5)2 (y 10)2 ¬49 15. If d 20, r 10. (x h)2 (y k)2 ¬r2 (x 0)2 (y 5)2 ¬102 x2 (y 5)2 ¬100 16. If d 16, r 8. (x h)2 (y k)2 ¬r2 [x (8)]2 (y 8)2 ¬82 (x 8)2 (y 8)2 ¬64 17. If d 24, r 12. (x h)2 (y k)2 ¬r2 [x (3)]2 [y (10)]2 122 (x 3)2 (y 10)2 ¬144 18. The distance between the center and the endpoint of the radius is r [0 ( 3)]2 (6 6)2 or 3. 2 2 2 (x h) (y k) ¬r [x (3)]2 (y 6)2 ¬32 (x 3)2 (y 6)2 ¬9 2 2 2 (2) , 19. The midpoint of the diameter is 2 2 h)2

k)2

¬r2

y

5 units

y3 x O

x2 The line x 2 is perpendicular to a radius. Since x 2 is a vertical line, the radius lies on a horizontal line. Count 5 units to the right from x 2. Find the value of h. h 2 5 or 7 Likewise, the radius perpendicular to the line y 3 lies on a vertical line. The value of k is 5 units up from 3. k 3 5 or 8 The center is at (7, 8) and the radius is 5. (x h)2 (y k)2 r2 (x 7)2 (y 8)2 52 (x 7)2 (y 8)2 25 24. x2 y2 25 Write the equation in standard form. (x 0)2 (y 0)2 52 The center is at (0, 0), and the radius is 5.

8

or (0, 0). The distance from (0, 0) to either endpoint, say (2, 2) is r (2 0 )2 ( 2 0)2 or 8. 2 2 (x h) (y k) r2 (x 0)2 (y 0)2 ( 8)2 x2 y2 8 20. Find the center, which is the midpoint of the

y

4 8

4

O

4

8x

4 8

15 7 6 , 22 or (11, 2). Then find diameter: 2

25. x2 y2 36 Write the equation in standard form. (x 0)2 (y 0)2 62 The center is at (0, 0), and the radius is 6.

r, the distance from (11, 2) to (7, 2). 2 ( r [7 (11)] 2 2)2 or 32 . 2 2 2 (x h) (y k) ¬r [x (11)]2 (y 2)2 ¬( 32)2 (x 11)2 (y 2)2 ¬32

8

y

4

21. The distance between the center and the endpoint 2 of the radius is r [1 (2)] (0 1)2 or 10 2 2 2 (x h) (y k) ¬r [x (2)]2 (y 1)2 ¬( 10)2 (x 2)2 (y 1)2 ¬10

Chapter 10

(7, 8)

5 units

8

4

O 4 8

374

4

8x

26. x2 y2 1 0 Write the equation in standard form. x2 y2 1 (x 0)2 (y 0)2 12 The center is at (0, 0), and the radius is 1.

29. (x 1)2 (y 2)2 9 Compare each expression in the equation to the standard form. (x h)2 ¬(x 1)2 (y k)2 ¬(y 2)2 x h ¬x 1 y k ¬y 2 h ¬1 k ¬2 h ¬1 k ¬2 r2 9, so r 3. The center is at (1, 2), and the radius is 3.

y

y

x

O

O ( 1, 2)

27. x2 y2 49 0 Write the equation in standard form. x2 y2 49 (x 0)2 (y 0)2 72 The center is at (0, 0), and the radius is 7. 8

30. Explore: You are given three points that lie on a circle. Plan: Graph ABC. Construct the perpendicular bisectors of two sides to locate the center. Find the length of the radius. Use the center and radius to write the equation.

y

4 8

O

4

4

x

8x

y

4 8

28. (x 2)2 (y 1)2 4 Compare each expression in the equation to the standard form. (x h)2 ¬(x 2)2 (y k)2 ¬(y 1)2 x h ¬x 2 y k ¬y 1 h ¬2 k ¬1 r2 4, so r 2. The center is at (2, 1), and the radius is 2.

x

C(2, 0)

Solve: The center is at (2, 2). Find r by using the center and a point on the circle, (2, 0). r (2 2 )2 (0 2)2 or 2 Write an equation. (x 2)2 (y 2)2 22 (x 2)2 (y 2)2 4 Examine: Verify the location of the center by finding the equations of the two bisectors and solving a system of equations. The perpendicular bisector of A B is the vertical line with equation x 2. Next find the equation of 0 2 the 1 bisector of A C. The slope of A C is 2 0 1. The slope of the bisector is 1. The midpoint of A C (1, 1). Use the point-slope form. y 1 1(x 1) yx Substitute x 2 to find the intersection. y2 The intersection is (2, 2) so the center is correct.

y

(2, 1) O

B(4, 2)

A(0, 2)

x

375

Chapter 10

so the slope of its bisector is 2 9 . The midpoint of C B is (2, 3). Use the slope and the midpoint to write an equation for the bisector of B C :

31. Explore: You are given three points that lie on a circle. Plan: Graph ABC. Construct the perpendicular bisectors of two sides to locate the center. Find the length of the radius. Use the center and radius to write the equation.

2 3 y 2 9 x 9 . Solving the system of equations, 23 y 4x 5 and y 2 9 x 9 , yields (2, 3),

which is the circumcenter. Let (2, 3) be D, then DA DB DC 85 . 35. The center is at (0, 0) and the radius is 7. (x h)2 (y k)2 r2 (x 0)2 (y 0)2 72 x2 y2 49 36. concentric circles

y

C(3, 3)

B(0, 0) x

A(6, 0)

2 6 37. The radius is 2 or 13. 38. (x 6)2 (y 2)2 36

Solve: The center is at (3, 0). Find r by using the center and a point on the circle, (0, 0). r (0 0)2 [0 (3)]2 or 3 write an equation. [x (3)]2 (y 0)2 ¬32 (x 3)2 y2 ¬9 Examine: Verify the location of the center by finding the equations of the two bisectors and solving a system of equations. The bisector of A B is the vertical line with equation x 3. Next find the equation of the bisector of A C . 3 0 The slope of A C 1. So the slope of 3 (6) the bisector is 1. (6) 0 3 Find the midpoint of A C : , 3 2 2

3 9 2, 2

8

x 4 4

4

8

12

8

9 y 3 2 ¬x 2

2y 3 ¬2x 9 2x 2y ¬6 x y ¬3 Substitute x 3 to find the intersection. 3 y 3 y0 The intersection is (3, 0) so the center is correct.

39.

32. (x 2)2 (y 2)2 r2 The center is at (2, 2). Find r by using the Distance Formula with the center and the point (2, 5).

40.

r (2 2 )2 (5 2)2

41. 42.

9 or 3 33. (x 5)2 (y 3)2 r2 The center is at (5, 3). Find r by using the Distance Formula with the center and the point (5, 1). r (5 5 )2 (1 3)2 4 or 2 34. The slope of A C is 1 4 , so the slope of its bisector is 4. The midpoint of A C is (0, 5). Use the slope and the midpoint to write an equation for the C : y 4x 5. The slope of B C is 9 bisector of A 2,

Chapter 10

y = 2x 2

4

Use the point-slope form. 9 y 3 2 ¬1 x 2

y

376

Solve algebraically for the intersection of the two graphs. Substitute 2x 2 for y in the equation of the circle. (x 6)2 (2x 2 2)2 ¬36 x2 12x 36 (2x)2 ¬36 5x2 12x ¬0 x(5x 12) ¬0 x 0 or 5x 12 0 x 2.4 y 2x 2 y 2(0) 2 or y 2(2.4) 2 2 2.8 The line is a secant because it intersects the circle at (0, 2) and (2.4, 2.8). x2 4x y2 8y ¬16 (x2 4x 4) (y2 8y 16) ¬16 4 16 (x 2)2 (y 4)2 ¬36 (x 2)2 [y (4)]2 ¬62 The center is at (2, 4), and the radius is 6. The center is at (58, 55), and the radius is 80. (x h)2 (y k)2 ¬r2 [x (58)]2 (y 55)2 ¬802 (x 58)2 (y 55)2 ¬6400 See students’ work. The center is at (0, 0), and the radius is 185 1740 or 1925. (x h)2 (y k)2 ¬r2 (x 0)2 (y 0)2 ¬(1925)2 x2 y2 ¬3,705,625

43a.

44. Sample answer: Equations of concentric circles; answers should include the following. • (x h)2 (y k)2 r2 • x2 y2 9, x2 y2 36, x2 y2 81, x2 y2 144, x2 y2 225 45. B; x2 y2 4x 14y 53 ¬81 (x2 4x) (y2 14y) ¬28 2 (x 4x 4) (y2 14y 49) ¬28 4 49 (x 2)2 (y 7)2 ¬81 [x (2)]2 (y 7)2 ¬92 The center is at (2, 7) and the diameter is 2(9) or 18. 46. D; there are 2 pints in one quart and 4 quarts in one gallon, so there are 8 pints in one gallon. One of the 8 pints is gone, so 7 of the 8 pints are left, or 7 8.

y (0, 3)

2

2

x y 9

x

(3, 0)

y x 3 Substitute x 3 for y in the equation of the circle. x2 (x 3)2 ¬9 2 x x2 6x 9 ¬9 2x2 6x ¬0 2x(x 3) ¬0 2x 0 or x 3 ¬0 x0 x ¬3 yx3 y 0 3 or y 3 3 3 0 The intersection points are (0, 3) and (3, 0). 43b.

Page 580 Maintain Your Skills 47. AX EX or 24 48. (DX)2 (DE)2 (EX)2 (DX)2 72 242 (DX)2 625 DX 25 49. DX ¬QX QD 25 ¬QX 7 18 ¬QX 50. TX DX DT TX 25 7 or 32 51. 360 (117 125) 118 x 1 2 (118) or 59

x 2y 2 = 25

y

x 2y 2 = 9 x

Since x2 y2 25 and x2 y2 9, 25 9. This is never true, so there are no intersection points. 43c.

52. 360 (100 120 90) 50 x 1 2 (120 50)

y

1 2 (70) or 35

(x3)2y 2 = 9

53. 180 (45 130) 5 x 1 2 (45 5) (0, 0)

1 2 (40) or 20

x

54. A(3, 2) → A(3 3, 2 4) or A(6, 6) B(4, 1) → B(4 3, 1 4) or B(1, 3) C(0, 4) → C(0 3, 4 4) or C(3, 0) 55. A(3, 2) → A(3, 2) B(4, 1) → B(4, 1) C(0, 4) → C(0, 4) 56. Each child needs 2(12) 2(10) 44 inches plus 1 inch overlap, or 45 inches total. The teacher 11 25 needs 25 45 1125 inches, or 36 31.25 yards.

(x3)2y 2 = 9 Since (x 3)2 y2 9 and (x 3)2 y2 9, (x 3)2 y2 ¬(x 3)2 y2 (x 3)2 ¬(x 3)2 2 x 6x 9 ¬x2 6x 9 6x ¬ 6x 12x ¬0 x ¬0 Substitute x ¬0 into the equation of either circle. (0 3)2 y2 ¬9 32 y2 ¬9 9 y2 ¬9 y2 ¬0 y ¬0 The intersection point is (0, 0).

Chapter 10 Study Guide and Review Page 581 1. 3. 5. 7. 9.

377

a h b d c

Vocabulary and Concept Check 2. 4. 6. 8. 10.

j i f g e

Chapter 10

20. BCA is a semicircle. 180 mBCA mAGB. 21. AB is a minor arc, so mAB mAB mAGB 30 mAB 22. mAGC mCGD ¬90 mAGB mBGC ¬mAGC 30 mBGC ¬90 mBGC ¬60 ¬60 mBC mFGD. 23. FD is a minor arc, so mFD Vertical angles are congruent. FGD ¬AGB mFGD mAGB ¬mAGB mFD ¬30 mFD 24. CDF is composed of adjacent arcs, CD and mCD mDF mCDF 90 30 or 120 mCDF 25. BCD is composed of adjacent arcs, BC and mBC mCD mBCD 60 90 or 150 mBCD 26. FAB is a semicircle. 180 mFAB 27. C 2r C 2(6) or 12 mDIG 180 2(mDGI) mDIG 180 2(24) or 132 Let arc length.

Pages 581–586 Lesson-by-Lesson Review 11. r 1 2d r 1 2 (15) or 7.5 in.

C d C (15) C 47.12 in. 12. d 2r d 2(6.4) or 12.8 m C d C (12.8) C 40.21 m 13. C ¬2r 68 ¬2r 68 2 ¬r 10.82 yd ¬r d 2r

68 d2 2

d 21.65 yd 14. r 1 2d r 1 2 (52) or 26 cm

C 2r C 2(26) C 163.36 cm 15. C ¬2r 138 ¬2r 13 8 2 ¬r

13 2 360 (12) ¬ 2 2 5 ¬

13 8 d2 2

17.

18.

19.

2 2 The length of DG is 5 units. 28. WN IW 5 and IW is a radius. C 2r C 2(5) or 10 Since IWN is equilateral, mWIN 60. Let arc length.

d 43.93 ft d 2r d 2(11) or 22 mm C d C (22) C 69.12 mm mBPY mYPC mCPA ¬180 3x (3x 3) (2x 15) ¬180 8x 12 ¬180 8x ¬168 x ¬21 mYPC. YC is a minor arc, so mYC mYPC mYC 3x 3 mYC 3(21) 3 or 60 mYC mBPC. BC is a minor arc, so mBC BC is composed of adjacent arcs, BY and YC. mBC mBY mYC mBPY mYPC mBC 3x (3x 3) mBC 6x 3 mBC 6(21) 3 or 123 mBC 360 mBCX mBX mBX 360 (3x 3x 3 2x 15 3x) 360 (11x 12) mBX 360 [11(21) 12] mBX 360 243 or 117 mBX

Chapter 10

CD.

13 2 360 ¬ 12

21.96 ft ¬r d 2r

16.

DF.

60 36 0 ¬ 10

60 36 0 (10) ¬ 5 ¬ 3

The length of WN is 5 3 units.

29. SV 1 2 SU

SV 1 2 (20) or 10 30. WZ 1 2 YW WZ 1 2 (20) or 10

31. RT bisects S U , so UV SV. UV SV UV 10 2mYX . 32. R X bisects YW, so mYW mYW 2mYX 2(45) or 90 mYW 33. SU YW and R X bisects YW, R T bisects SU. mST mYX 45 mST

378

mYW . 34. Since SU YW, mSU mSU mYW 90 mSU 35. m1 1 2 (96) or 48 36. 2 is a right angle because it intercepts a semicircle. m2 90 37. Inscribed angles of the same arc are congruent. m3 32 38. m3 1 mGH

45. 26 ¬1 2 (89 x) 52 ¬89 x x ¬37 46. 33 ¬1 2 (x 51) 66 ¬x 51 117 ¬x 47. 7(7 x) ¬132 49 7x ¬169 7x ¬120 x ¬17.1 48. 8.1x ¬10.3(17) 8.1x ¬175.1 x ¬21.6 49. x(15 x) ¬8(8 12) 15x x2 ¬160 x2 15x 160 ¬0 2 4ac b b x

2

1 2 (78) or 39

m2 m3 ¬90 m2 39 ¬90 m2 ¬51 m1 m2 ¬90 m1 51 ¬90 m1 ¬39 39. m2 m3 ¬90 2x x ¬90 3x ¬90 x ¬30 m2 2x 2(30) or 60 m3 x or 30 m1 m2 ¬90 m1 60 ¬90 m1 ¬30 40. m2 1 2 mJH

2a 15 (15)2 4(1)(160) x 2(1) 29.4 15 x 2

50.

51.

1 2 (114) or 57

52.

m2 m3 ¬90 57 m3 ¬90 m3 ¬33 m1 m2 ¬90 m1 57 ¬90 m1 ¬33 41. x2 122 ¬152 x2 144 ¬225 x2 ¬81 x ¬9 42. x2 92 ¬(6 9)2 x2 92 ¬152 x2 81 ¬225 x2 ¬144 x ¬12 43. 72 242 ¬(x 7)2 49 576 ¬x2 14x 49 0 ¬x2 14x 576 (x 18)(x 32) ¬0 x ¬18 ¬0 or x ¬32 ¬0 x ¬18 x ¬32 Disregard the negative value. So x ¬18.

53.

x 7.2 or x 44.4 Disregard the negative value. So x 7.2. (x h)2 (y k)2 ¬r2 (x 0)2 (y 0)2 ¬(5 )2 x2 y2 ¬5 If d 6, r 3. (x h)2 (y k)2 ¬r2 [x (4)]2 (y 8)2 ¬32 (x 4)2 (y 8)2 ¬9 The center is at the midpoint of the diameter. 8 4 4 0 center 2 , 2 or (4, 4) The radius is the distance from the center to (0, 4). 2 [ r (0 4) 4 ( 4)]2 16 or 4 Write the equation. (x h)2 (y k)2 ¬r2 (x 4)2 [y (4)]2 ¬42 (x 4)2 (y 4)2 ¬16 Since x 1 is a vertical line, the radius lies on a horizontal line. Count horizontally from the point (1, 4) to the line x 1 to find the radius. The radius is 2.

y

x

(x h)2 (y k)2 ¬r2 [x (1)]2 (y 4)2 ¬22 (x 1)2 (y 4)2 ¬4

44. x 1 2 (68 24) 1 x 2(44) or 22

379

Chapter 10

54. x2 y2 2.25 Write the equation in standard form. (x 0)2 (y 0)2 (1.5)2 The center is at (0, 0), and the radius is 1.5.

midpoint of B C . The equation is y 3. The intersection of x 3 and y 3 is the point (3, 3). This is the center we found above so the answer checks.

y

57.

y

A(0, 6) O

C(6, 6)

x

B(6, 0) O

55. (x 4)2 (y 1)2 9 Compare each expression in the equation to the standard form. (x h)2 ¬(x 4)2 (y k)2 ¬(y 1)2 x h ¬x 4 y k ¬y 1 h ¬4 k ¬1 h ¬4 k ¬1 r2 9, so r 3. The center is at (4, 1), and the radius is 3.

Chapter 10 Practice Test Page 587 1. Sample answer: A chord is a segment that has its endpoints on a circle. A secant contains a chord and is a segment that intersects a circle in two points. A tangent intersects a circle in exactly one point and no point of the tangent lies in the interior of the circle. 2. Find the midpoint of the diameter using the Midpoint Formula with the coordinates of the diameter’s endpoints. 3. C ¬2r 25 ¬2r 25 ¬2r 12.5 ¬r The radius is 12.5 units. 4. N A , N B , N C , and N D are radii. 2 4 5. The diameter is A D , so the radius is 2 or 12. CN 12 6. No; the diameter is the longest chord of a circle. 7. r AN or 5 C 2r C 2(5) or 10 The circumference is 10 meters. mBNC, mBC 20 8. BC is a minor arc so mBC 9. AD is composed of adjacent arcs, AB, BC, and CD. AD is a semicircle. ¬mAB mBC mCD mAD 180 ¬mAB 30 mAB 150 ¬2mAB 75 ¬mAB 10. B E E D mED mBE mBE 120 . 11. ADE is an inscribed angle intercepting AE 1 mADE mAE

y

x

O

56. Explore: You are given three points that lie on a circle. Plan: Graph ABC. Construct the perpendicular bisectors of two sides to locate the center. Find the length of the radius. Use the center and radius to write the equation. y

A (0,6)

C(6,6)

B(6,0) x Solve: The center is at (3, 3). Find r by using the center and a point on the circle, (0, 6). r (0 3 )2 (6 3)2 or 18 Write an equation. 2 (x 3)2 (y 3)2 18 (x 3)2 (y 3)2 18 Examine: Verify the location of the center by finding the equations of the two bisectors and solving a system of equations. bisector of A C: Since A C is horizontal, its bisector is vertical. It goes through (3, 6), the midpoint of A C . The equation is x 3. bisector of B C: Since B C is vertical, its bisector is horizontal. It goes through (6, 3), the Chapter 10

x

2 1 2(75) or 37.5

12. If two segments from the same exterior point are tangent to a circle, then they are congruent. x 15

380

62 ¬x(x 5) 36 ¬x2 5x 0 ¬x2 5x 36 0 ¬(x 4)(x 9) x 4 ¬0 or x 9 ¬0 x ¬4 x ¬9 Discard x 9. So x ¬4. 14. 5x 6(8) 5x 48

23. Sample answer: Given: X with diameters S R and T V Prove: RT VS

13.

R T X V S

Proof: Statements

Reasons

1. X with diameters S R and T V 2. RXT VXS 3. mRXT mVXS mVS 4. mRT

48 x 5 or 9.6 15. Draw the radius to the point of tangency. Use the Pythagorean Theorem. 62 82 ¬(x 6)2 36 64 ¬x2 12x 36 0 ¬x2 12x 64 0 ¬(x 4)(x 16) x 4 ¬0 or x 16 ¬0 x ¬4 x ¬16 Discard x 16. So x ¬4. 16. 5(5 x) ¬4(4 7) 25 5x ¬16 28 5x ¬19

5. RT VS

1. Given 2. Vertical are . 3. Def. of 4. Measure of arc equals measure of its central angle. 5. Def. of arcs

24. Let x the distance from the center to the 5-inch side. x2 (2.5)2 ¬42 x2 6.25 ¬16 x2 ¬9.75 x ¬3.1 The height is about 4 3.1 or 7.1 in. 25. A; draw the segment from C to A. DB CA. Since diagonals of a rectangle are congruent. DB r

19 x ¬ 5 or 3.8 17. 35 1 2 [(360 x) x]

70 360 2x 2x 290 x 145 18. 180 (45 110) 25 x 1 2 (45 25) 1 2 (20) or 10


19. 80 1 2 (110 x) 160 110 x 50 x 20. C d C (50) C 157 The circumference is about 157 ft. 21. If d 50, r 25. (x h)2 (y k)2 ¬r2 [x (2)]2 (y 5)2 ¬252 (x 2)2 (y 5)2 ¬625 22. (x 1)2 (y 2)2 4 Compare each expression in the equation to the standard form. (x h)2 ¬(x 1)2 (y k)2 ¬(y 2)2 x h ¬x 1 y k ¬y 2 h ¬1 k ¬2 r2 4, so r 2. The center is at (1, 2), and the radius is 2.

Pages 588–589 1. A; 3y 6x 9 is the same as y 2x 3. So the line has slope m ¬2 and y-intercept (0, 3). The graph that satisfies these conditions is A. 2. C; m1 ¬m2 6x 5 ¬3x 13 6x 3x ¬13 5 3x ¬18 x ¬6 Use x to find the measure of 1. m1 6x 5 6(6) 5 36 5 or 31 3. A 4. B; 3(x 2) ¬2x 9 3x 6 ¬2x 9 x ¬3 Use x to find the measure of one side. x 2 3 2 or 5 Each side is 5 miles long.

y O x

x2

x2

x2

381

Chapter 10

13. ABC is a semicircle. 18 0 mABC 2 or 90 14. DF AD or 12 DE DF FE DE 12 18 or 30 Since A E is a tangent, CAE is a right angle and AED is a right triangle. Use the Pythagorean Theorem. (AE)2 (AD)2 ¬(DE)2 (AE)2 (12)2 ¬302 (AE)2 144 ¬900 (AE)2 ¬756 AE ¬27.5 15. (BK)(KC) ¬(KF)(JK) 8(12) ¬16(JK) 96 ¬16(JK) 6 ¬JK 16a. V X and W Y 16b. Let w width, then 3w 2 length 2(3w 2) 2w ¬164 6w 4 2w ¬164 8w ¬160 w ¬20 The width is 20 in. and the length is 3(20) 2 or 62 in. 17a. y B(1, 6)

5. A 6. D is a semicircle. 7. C; DEA DEA is composed of adjacent arcs, DE and EA. ¬mDE mEA mDEA mDEA ¬mDFE mEA 180 ¬36 mEA 144 ¬mEA 8. C; the measure of a minor arc is the measure of its central angle. 9. D 10. mGDE mGED mDGE ¬180 35 85 mDGE ¬180 120 mDGE ¬180 mDGE ¬60 In DGE, G E is the shortest side because it is opposite the smallest angle. mFGE mGEF mF ¬180 65 55 mF ¬180 120 mF ¬180 mF ¬60 In GFE, FG GE because mGEF mF. So FG is the shortest side of quadrilateral DEFG. 11.

ST 30 8 ¬ 12

12(ST) ¬8(30) 12(ST) ¬240 ST ¬20 ST is 20 ft long. 12. Find a correspondence between ABC and DEF so that their sides are proportional. 12

y

F

8 C

D

4

O

E

4

17b. The center is the midpoint of the diameter: 8

1 2 6 1 2 , 2 or (1, 2).

x 12

17c. Find r by using the Distance Formula. Find the distance between the center and a point on the circle, (1, 2). r (1 1 )2 ( 2 2)2 16 or 4 17d. C 2r C 2(4) or 8 units 17e. The center is at (1, 2), and the radius is 4. (x h)2 (y k)2 r2 (x 1)2 (y 2)2 42 (x 1)2 (y 2)2 16

4

AC 7 1 6 DE 10 7 3 2 (4 AB (6 0) 1)2 36 9 45

EF (10 8.5)2 (7 10)2 2 (1.5) 9 11.25 2 (4 BC (6 0) 7)2 45 DF (8.5 7)2 (10 7)2 45 2 (1.5) 9

AC BC AB D E EF DF 2.

11 14 245

2

So the scale factor is 2.

Chapter 10

x

A(1, 2)

B

A 4

(1, 2)

382

Chapter 11 Areas of Polygons and Circles 4. co- together, centr- center; circles with a common center 5. circum- around, scribe- write; to write around (a geometrical figure) 6. co- together, linear- line; together on the same line 7. circum- around, about; ferre- to carry 8. Sample answers: polychromatic – multicolored, polymer – a chemical compound composed of a repeating structural unit, polysyllabic – a word with more than three syllables

Page 593 Getting Started A ¬ w 150 ¬ 15 10 ¬ 3. A ¬ w 21.16 ¬ 4.6 4.6 ¬ 5. A ¬ w 450 ¬ 25 18 ¬ 1.

2. A ¬ w 38 ¬ 19 2 ¬ 4. A ¬ w 2000 ¬ 32 62.5 ¬ 6. A ¬ w 256 ¬ 20 12.8 ¬

1 7. 1 2 a(b c) ¬ 2 6(8 10)

¬1 2 6(18) 54

11-1 Areas of Parallelograms

1 8. 1 2 ab 2 6 8 24 1 9. 1 2 (2b c) ¬ 2 (2 8 10)

Page 595 Geometry Activity

¬1 2 (16 10)

1. When the parallelogram is folded, the base of the rectangle is 4 and the height is 5. So the area is 20 units2. 2. There are 2 rectangles, one on the bottom and one formed by the folded triangles on top. 3. 40 units2 4. The base of the parallelogram is half of the length of the rectangle. The altitude of the parallelogram is the same width as the width of the rectangle. 5. A w or A bh

¬1 2 26 13 1 10. 1 2 d(a c) ¬ 2 11(6 10) ¬1 2 11 16

¬8 11 88 (b c) ¬1(8 10) 11. 1 2 2 ¬1 2 (18) ¬9

1 12. 1 2 cd ¬ 2 10 11 ¬55 13. ABD is a 30°-60°-90° triangle. B D , or h, is the longer leg, A D is the shorter leg, and B A is the hypotenuse. AD ¬1 2 AC or 6 h ¬6 3

B

Page 598 Check for Understanding 1. The area of a rectangle is the product of the length and the width. The area of a parallelogram is the product of the base and the height. For both quadrilaterals, the measure of the length of one side is multiplied by the length of the altitude. 2. See students’ work. 3. P 2(5) 2(9) 28 ft Use a 30°-60°-90° triangle to find the height, with x as the length of the shorter leg. 9 ¬2x 9 ¬x 2

h 60˚

A

D

C

12

14. In the 30°-60°-90° triangle, the hypotenuse has a length of 22, so the shorter leg has a length of 11. 15. In the 45°-45°-90° C triangle, the length of the h hypotenuse is 15. 45˚ AB ¬BC 2 B A 15 ¬h 2 15

height x3 923 ft A ¬bh

15 ¬h 2 15 2 ¬h 2 2 15 2 ¬h 2

¬59 2 3 4 5 ¬ or about 39.0 ft2 2 3

The perimeter of the parallelogram is 28 ft, and the area is about 39.0 ft2. 4. P 2(13) 2(10) 46 yd Use a 45°-45°-90° triangle to find the height, x. 10 ¬x 2

Page 594 Reading Mathematics 1. bi- 2, sector- a subdivision or region; divide into 2 regions 2. poly- many, gon- closed figure; closed figure with many sides 3. equi- equal, lateral- sides; having sides of equal length

10 x 2 10 2 ¬x 2 2

52 ¬x height x 52 yd

383

Chapter 11

A ¬bh

A ¬bh ¬217 517 10 17 ¬170 units2 8. Left Parallelogram Rectangle A ¬bh A ¬w 18 15 35 18 ¬270 ft2 ¬630 ft2 Right Parallelogram A ¬bh 18 15 ¬270 ft2 The total area is 270 630 270 or 1170 ft2.

¬1352 ¬652 or about 91.9 yd2 The perimeter of the parallelogram is 46 yd, and the area is about 91.9 yd2. 5. P 4(3.2) 12.8 m A ¬s2 ¬(3.2)2 ¬10.24 or about 10.2 m2 The perimeter of the square is 12.8 m, and the area is about 10.2 m2. 6.

Pages 598–600 Practice and Apply 9. P 2(30) 2(10) 80 in. Use a 30°-60°-90° triangle to find the height, with x as the length of the shorter leg. 10 ¬2x 5 ¬x height x 3 5 3 in. A ¬bh ¬305 3 ¬150 3 or about 259.8 in2. The perimeter of the parallelogram is 80 in., and the area is about 259.8 in2. 10. Use the 45°-45°-90° triangle with hypotenuse 4 to find the base and height of the parallelogram, both equal to x. 4 x 2 4 x 2 4 2 x 2 2 2 2 ¬x base height x 2 2m P 22 2 2(4) 4 2 8 or about 13.7 m A ¬bh

y

V ( 2, 6)

T ( 0, 0)

X ( 6, 6)

x

Y ( 4, 0)

6 0 6 slope of T V 2 0 2 or 3

0 6 6 Y slope of X 4 6 2 or 3

6 6 0 X slope of V 6 2 4 or 0

0 0 0 slope of T Y 4 0 4 or 0 TVXY is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. A ¬bh ¬4 6 ¬24 units2

7.

¬22 22 ¬8 m2 The perimeter of the parallelgram is about 13.7 m, and the area is 8 m2. 11. Since all 4 sides have the same measure and the angle is a right angle, the parallelogram is a square. P 4(5.4) 21.6 cm A ¬s2 ¬(5.4)2 ¬29.16 or about 29.2 cm2 The perimeter is 21.6 cm, and the area is about 29.2 cm2. 12. P 2(15) 2(10) 50 in. Use a 45°-45°-90° triangle to find the height, x. 10 ¬x 2 10 2 x 2 2 5 2 ¬x height x 5 2 in. A ¬bh ¬155 2 ¬75 2 or about 106.1 in2 The perimeter is 50 in., and the area is about 106.1 in2.

y V ( 2, 18)

T ( 10, 16)

X ( 3, 2)

x

Y ( 5, 4)

16 18 2 1 slope of T V 2 10 8 or 4

4 (2) 2 1 slope of X Y 5 (3) 8 or 4 2 18 2 0 slope of V X 3 2 5 or 4

16 4 2 0 Y slope of T 5 10 5 or 4 TVXY is a rectangle, since opposite sides have the same slope and the slopes of consecutive sides are negative reciprocals of each other. 2 Length of X Y is [5 (3)] [4 (2 )]2 2 17. Length of T Y is [10 5]2 [16 (4)]2 5 17.

Chapter 11

384

13. P 2(12) 2(10) 44 m Use a 30°-60°-90° triangle to find the height, with x as the length of the shorter leg. 10 ¬2x 5 ¬x height x 3 5 3m A ¬bh ¬125 3 ¬60 3 or about 103.9 m2 The perimeter is 44 m, and the area is about 103.9 m2. 14. P 2(5.4) 2(4.2) 19.2 ft A ¬bh ¬(5.4)(4.2) ¬22.68 or about 22.7 ft2 The perimeter is 19.2 ft, and the area is about 22.7 ft2. 15. Rectangle A ¬w

A ¬bh 100 ¬(x 15)(x) 100 ¬x2 15x x2 15x 100 ¬0 (x 20)(x 5) ¬0 x 20 ¬0 or x 5 ¬0 x ¬20 or x ¬5 Reject the negative solution. h 5 units, b 20 units 19. A ¬bh 2000 ¬(x 10)(x) 2000 ¬x2 10x 2 x 10x 2000 ¬0 (x 40)(x 50) ¬0 x 40 ¬0 or x 50 ¬0 x ¬40 or x ¬50 Reject the negative solution. h 40 units, b 50 units 20. y 18.

D ( 1, 5) C ( 5, 5)

1052 ¬502 mm2 Each triangle A ¬1 2 bh 1 2 (5)(5)

A ( 0, 0)

2 5 2 ¬ 2 mm 5 The shaded area is 502 222 or about 45.7 mm2. 16. Rectangular outline A ¬w (7 4 7)(15) ¬270 cm2 Upper cutout A ¬w 12 3 ¬36 cm2 Lower cutout A ¬w 48 ¬32 cm2 The shaded area is 270 36 32 or 202 cm2. 17. Big square A ¬s2 (9.2)2 ¬84.64 ft2 Small square A ¬s2 (3.1)2 ¬9.61 ft2 Rectangle A ¬w (10.8)(3.1) ¬33.48 ft2 The shaded area is 84.64 33.48 9.61 or about 108.5 ft2.

B ( 4, 0)

x

0 0 0 slope of A B 4 0 4 or 0

5 5 0 slope of D C 5 1 4 or 0

5 0 5 D slope of A 1 0 1 or 5

5 0 5 C slope of B 5 4 1 or 5 ABCD is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. Base: A B lies along the x-axis and is horizontal so AB 4 0 4. Height: Since C D and A B are horizontal segments, the distance between them, or height, can be measured on any vertical segment. Reading from the graph, the height is 5. A ¬bh ¬4 5 ¬20 units2

21. H ( 3, 4)

y

G ( 5, 4)

x

E ( 5, 3)

F ( 3, 3)

3 (3) 0 slope of E F 3 (5) 8 or 0 4 4 0 G slope of H 5 ( 3) 8 or 0

385

Chapter 11

2 6 8 slope of O P 4 2 2 or 4 NOPQ is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. Base: P Q is horizontal with length 4 4 8. Height: Since P Q and O N are horizontal segments, the distance between them, or height, can be measured on any vertical segment. Reading from the graph, the height is 8. A ¬bh ¬8 8 ¬64 units2

3) 4 ( 7 slope of F G 53 2

4 (3) 7 slope of E H 3 (5) 2 EFGH is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. Base: E F is horizontal with length 3 (5) 8. Height: Since G H and E F are horizontal segments, the distance between them, or height, can be measured on any vertical segment. Reading from the graph, the height is 7. A ¬bh ¬8 7 ¬56 units2

22.

y M ( 1, 6)

24. R ( 2, 4)

L ( 6, 6)

y

S ( 8, 4)

x

x

U ( 2, 3)

K ( 4, 4)

J ( 1, 4)

T ( 8, 3)

0 3 (3) slope of U T or 0 8 (2) 10

4 (4) 0 slope of J K 4 (1) 5 or 0

4 4 0 slope of R S 8 ( 2) 10 or 0

6 ( 4) 1 0 M slope of J 1 (1) 2 or 5

4 3 7 T slope of S 8 8 0 is undefined RSTU is a rectangle, since the sides are not all equal but are all horizontal or vertical. Base: U T is horizontal with length 2 8 10. Height: Since R S and U T are horizontal segments, the distance between them, or height, can be measured on any vertical segment. Reading from the graph, the height is 7. A ¬bh ¬10 7 ¬70 units2

3 4 7 U slope of R 2 (2) 0 is undefined

6 6 0 L slope of M 6 1 5 or 0

4) 6 ( 10 L slope of K 6 4 2 or 5 JKLM is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. Base: J K is horizontal with length 1 4 5. Height: Since J K and L M are horizontal segments, the distance between them, or height, can be measured on any vertical segment. Reading from the graph, the height is 10. A ¬bh ¬5 10 ¬50 units2

23.

25.

V ( 1, 10) W ( 4, 8)

Y ( 1, 7)

y

N ( 6, 2)

y

O ( 2, 2)

X ( 2, 5)

x x

slope of

Q ( 4, 6)

P ( 4, 6)

slope of

6 (6) 0 slope of Q P 4 (4) 8 or 0

slope of

2 2 0 O slope of N 2 ( 6) 8 or 0

slope of

6 2 8 Q slope of N 4 (6) 2 or 4

Chapter 11

386

5 2 7 2 X Y 2 ( 1) 3 or 3 2 8 10 2 W V 4 1 3 or 3 8 5 3 W X 42 2 10 7 3 V Y 1 ( 1) 2

VWXY is a rectangle, since opposite sides have the same slope and the slopes of consecutive sides are negative reciprocals of each other. 2 X [2 (1)] [5 7]2 13 Length of Y 2 2 Length of X W [4 2] [8 5] 13 Thus VWXY is in fact a square. A ¬s2 2 ¬ 13 ¬13 units2 26. Guest bedroom Family room A ¬w A ¬w ¬20 22 ¬25 22 ¬440 ft2 ¬550 ft2 Hallway ¬A ¬w ¬25 3 ¬75 ft2 The Bessos need 440 550 75 or 1065 ft2 of carpet. Since there are 9 square feet per square yard, the family should order 1065 9 or 119 yd2 (rounded up to the nearest yd2). 27. The figure is composed of three 5 by 10 rectangles.

31. On the crosswalk, draw a 30°-60°-90° triangle whose hypotenuse is 16 ft long and whose short side lies along the left edge of the crosswalk. That short side measures 8 ft, and the remaining side, which represents the perpendicular distance between the stripes, measures 8 3 or about 13.9 ft. 32. P 2(8) 2(11) 38 m A bh 8 10 80 m2 The perimeter is 38 m, and the area is 80 m2. 33. P 2(4) 2(5.5) 19 m A bh 45 20 m2 The perimeter is 19 m and the area is 80 m2. 34. The new perimeter is half of the original perimeter. The new area is one half squared, or one fourth, the area of the original parallelogram. 35. Let the side length of one square be x. Then the 4x 48 side length of the other square is or 4 12 x. x2 (12 x)2 ¬74 2 x 144 24x x2 ¬74 2x2 24x 70 ¬0 x2 12x 35 ¬0 (x 5)(x 7) ¬0 x 5 or x ¬7 The two side lengths are 5 in. and 7 in. 36. Sample answer: Area is used when designing a garden to find the total amount of materials needed. Answers should include the following. • Find the area of one square and multiply by the number of squares in the garden. • Knowing the area is useful when planning a stone walkway or fencing in flowers or vegetables. 37. C; the length of base A B is 102 62 8, so the 2 area is 8 6 48 m . 38. D; either A, B, or C could be true, depending on 1 1 whether x 1 2 , x 2 , or x 2 .

10 5

5

3

7 7 5

5

7

7

5

5 3 10

For each rectangle, A w 5 10 or 50 units2. The total area is 3 50 or 150 units2. 28. The figure can be viewed as a large 8 by 11 rectangle with two rectangular cutouts measuring 1 by 2 and 3 by 3. Large rectangle Cutout 1 A ¬w A ¬w ¬8 11 ¬1 2 ¬88 units2 ¬2 units2 Cutout 2 ¬A ¬w ¬3 3 ¬9 units2 The shaded area is 88 2 9 or 77 units2. 29. The triptych measures 3 5 2 12 2 5 3 or 32 inches wide by 3 12 3 or 18 inches tall. Yes, it will fit in a 45-inch by 20-inch frame. 30. By Exercise 29, the artwork measures 32 inches by 18 inches. ¬A ¬w ¬32 18 ¬576 in2

Page 600 Maintain Your Skills 39. For the equation (x h)2 (y k)2 r2, the center of the circle is (h, k) and the radius is r. For the equation (x 5)2 (y 2)2 49 72, the center is (5, 2) and r 7. 40. For the equation (x h)2 (y k)2 r2, the center of the circle is (h, k) and the radius is r. For the equation (x 3)2 (y 9)2 81 0, which is equivalent to [x (3)]2 [y (9)]2 92, the center is (3, 9) and r 9. 41. For the equation (x h)2 (y k)2 r2, the center of the circle is (h, k) and the radius is r. For 2

2

1 4 the equation x 2 3 y 9 9 0, which 2 2 2 1 2 is equivalent to x 2 3 y 9 3 , 1 2 the center is 2 3 , 9 and r 3 .

387

Chapter 11

42. For the equation (x h)2 (y k)2 r2, the center of the circle is (h, k) and the radius is r. For the equation (x 2.8)2 (y 7.6)2 34.81, which is equivalent to [x 2.8]2 [y (7.6)]2 5.92, the center is (2.8, 7.6) and r 5.9.

49. Use the Pythagorean Theorem. a2 b2 ¬c2 52 122 ¬2 25 144 ¬2 169 ¬2 13 ¬ The length of plywood needed is 13 ft.

43. Use Theorem 10.16. 10(10 22) ¬8(8 x) 320 ¬64 8x 256 ¬8x 32 ¬x

1 50. 1 2 (7y) ¬ 2 (7 2) ¬7 1 51. 1 2 wx ¬ 2 (8)(4)

44. Use Theorem 10.15. 4 9 ¬x x 36 ¬x2 6 ¬x

¬16 1 52. 1 2 z(x y) ¬ 2 (5)(4 2)

15

45. Use Theorem 10.17. 14 14 ¬7(7 x) 196 ¬49 7x 147 ¬7x 21 ¬x 46.

B

1 53. 1 2 x(y w) ¬ 2 (4)(2 8)

20

A

11-2 Areas of Triangles, Trapezoids, and Rhombi

B

y

A

Page 601

C

C

x

C A

B Image coordinates: A (1, 3), B (4, 6), C (5, 1) The rotation angle is 180°. 47.

Geometry Activity

1. The two smaller triangles, combined, are the same size as ABC. 2. ABC is 1 2 the area of rectangle ACDE. 3. Since the area of rectangle ACDE is bh, for ABC A 1 2 bh.

Page 605 Check for Understanding 1. Sample answer:

y

F G, H

2. Kiku is correct; she simplified the formula by adding the terms in the parentheses before multiplying. 3. Sometimes; two rhombi can have different corresponding diagonal lengths and have the same area.

H, H

x

F

F G

G

4. A ¬1 2 d1d2 ¬1 2 (20)(24)

Image coordinates: F (4, 0), G (2, 2), H (2, 2) The rotation angle is 90° counterclockwise. 48.

¬240 m2 5. area of FGHI ¬area of FGH area of FHI 1 ¬1 2 bh1 2 bh2

y

L L

1 ¬1 2 (37)(9) 2 (37)(18)

M

33 3 ¬ 2 333

¬499.5 in2

N x

L

6. A ¬1 2 h(b1 b2) 1 ¬2(12)(24 16)

M M

N

¬240 yd2

N

Image coordinates: L (0, 2), M (3, 3), N (4, 1) The rotation angle is 90° counterclockwise. Chapter 11

388

7. AB is horizontal with length 5 2 7 or 7. Point C lies above B A a distance of 3 (3) 6 or 6 units. A ¬1 2 bh ¬1 2 (7)(6)


y

13. A ¬1 2 bh

C ( 1, 3)

B(5, 3) ¬21 units2 8. F G and H J are horizontal. FG ¬5 (1) y ¬6 or 6 F ( 1, 8) HJ ¬1 3 ¬2 or 2 h ¬8 4 ¬4 or 4 J ( 1, 4) h(b1 b2) A ¬1 2

¬1 2 (7.3)(3.4)

¬12.41 or about 12.4 cm2 14. A ¬1 2 bh

x

¬1 2 (10.2)(7)

¬35.7 ft2

A(2, 3)

15. A ¬1 2 h(b1 b2)

¬1 2 (10)(8 11) ¬95 km2

G(5, 8)

16. A ¬1 2 h(b1 b2)

¬1 2 (8.5)(8.5 14.2) ¬96.475 or about 96.5 yd2

H ( 3, 4)

¬1 2 (4)(6 2) x ¬16 units2 9. L P is horizontal, M Q is vertical. LP ¬0 (4) M ( 2, 4) y ¬4 or 4 MQ ¬2 4 L ( 4, 3) ¬2 or 2 P ( 0, 3) A ¬1 2 d1d2 ( 2, 2) Q ¬1 2 (4)(2) ¬4 units2

17. A ¬1 2 d1d2

¬1 2 (20 20)(30 30) ¬1200 ft2

18. A ¬1 2 d1d2

¬1 2 (17 17)(12 12) ¬408 cm2 19. area of quadrilateral ABCD area of ADC area of ABC D C

x

5m

5m 8m

A 10. A ¬1 2 h(b1 b2) Substitute the known values into the formula. 250 ¬1 2 h(20 30)

B 12 m

1 ¬1 2 b1h1 2 b2h2

1 ¬1 2 (8)(5) 2 (12)(5) 2 ¬50 m 20. area of quadrilateral WXYZ area of WXY area of WZY

250 ¬1 2 (50)h 250 ¬25h 10 ¬h The height is 10 in.

W

11. A ¬1 2 d1d2

Z 4 in.

6 in.

Substitute the known values into the formula.

18 in.

675 ¬1 2 (15 15)d2 675 ¬15d2 45 ¬d2 SU ¬45 m

X

21 in.

Y

1 ¬1 2 b1h1 2 b2h2

1 ¬1 2 (21)(6) 2 (18)(4) ¬99 in2 21. In a 30°-60°-90° right triangle, the longer leg is 3 times as long as the shorter leg. Here, then,

12. From Postulate 11.1, the area of each congruent 3 2 rhombus is the same, namely 827 8 13 6 8 in . The width of one rhombus is 15 5 3 in. To find the other diagonal (the height), use the area formula.

b h3 , so h b. 3 A bh

A ¬1 2 d1d2

15 15 3 75 3 or about 129.9 mm2

1 63 8 ¬ 2 (3)d2 51 3 8 ¬ 2 d2 17 4 ¬d2

17 1 The vertical diagonal measures 4 or 4 4 in.

389

Chapter 11

22. PT and Q R are horizontal. QR ¬5 3 ¬2 or 2 PT ¬6 0 ¬6 or 6 h ¬7 3 ¬4 or 4

27. JL is horizontal, KM is vertical. JL ¬3 (1) ¬4 or 4 KM ¬3 7 ¬10 or 10

y

Q

R

P

A ¬1 2 h(b1 b2)

T

¬16 units2 23. R T and P Q are horizontal. RT ¬4 4 ¬8 or 8 PQ ¬2 (4) T ¬2 or 2 h ¬6 (5) 8 4 ¬11 or 11 P

R

4

¬1 2 (6)(5 9)

Q R x

4

8

8

30. A 1 2 h(b1 b2) y

Solve for h. 750 1 2 h(35 25)

Q

750 ¬1 2 (60)h

x

T

750 ¬30h 25 ¬h The height is 25 m.

R

31. A 1 2 h(b1 b2) Solve for b2.

¬1 2 (5)(2 7)

¬22.5 units2 26. J L is horizontal, K M is vertical. JL 12 2 y 4 10 or 10 KM 2 4 J 6 or 6 4 A ¬1 4 2 d1d2 ¬1 2 (10)(6)

¬30 units2

Chapter 11

188.35 ¬1 2 (8.7)(16.5 b2)

376.7 ¬8.7(16.5 b2) 376.7 ¬143.55 8.7b2 233.15 ¬8.7b2 26.8 ¬b2 GK is about 26.8 ft.

K 4

x

4

8

4

8

4 M 8

y

4

K x

4

L

8

29. J L is horizontal, K M is vertical. JL ¬10 2 y ¬8 or 8 12 KM ¬2 6 ¬4 or 4 8 A ¬1 2 d1d2 4 J ¬1 2 (8)(4) ¬16 units2

¬42 units2 25. R T and P Q are horizontal. RT 4 (2) 2 or 2 P PQ 1 (6) 7 7 h 3 (2) 5 or 5

L

M

4

A ¬1 2 h(b1 b2)

4

¬36 units2

¬1 8 2 (11)(8 2) ¬55 units2 24. R T and P Q are horizontal. RT 1 6 y P 8 5 or 5 PQ 6 (3) 4 9 or 9 h 8 2 T 8 4 6 or 6

A ¬1 2 h(b1 b2)

8x

4

4 Q

K

J

28. JL is horizontal, KM is vertical. JL ¬5 (1) ¬6 or 6 KM ¬10 2 ¬12 or 12 8 4 A ¬1 2 d1d2 J ¬1 2 (6)(12)

y

8

y

8 4

¬20 units2

x

¬1 2 (4)(2 6)

A ¬1 2 h(b1 b2)

A ¬1 2 d1d2 1 ¬2 (4)(10)

8

8 M

L 12 x

32. A ¬1 2 d1d2 Solve for d2. 375 ¬1 2 (25)d2 375 ¬12.5d2 30 ¬d2 NQ 30 in.

8 12

390

K L M 4

8

12

x

33. A ¬1 2 d1d2 Solve for d2. 137.9 ¬1 2 (12.2)d2 137.9 ¬6.1d2 22.6 ¬d2 QS is about 22.6 m.

41. A side length of 52 4 or 13 in. and a halfdiagonal of 24 2 or 12 in. implies that the other 2 half-diagonal measures 13 122 or 5 in. So d2 2 5 or 10 in. 13 13 A ¬1 2 d1d2

34. A ¬1 2 bh

24 13

¬120 in2

Solve for b. 248 ¬1 2 b(16) 248 ¬8b 31 ¬b The base measures 31 in.

42.

2

2

1

¬156 yd2

2

43. b ¬1 3P

¬1 3 (15) ¬5 in. Drawing the height divides the triangle into two 30°-60°-90° triangles each with base 1 2 b.

38. A ¬1 2 h(b1 b2) ¬1 2 (122.81)(56 69.7)

h ¬3 12b

ft2

¬3 12(5) 3 5 ¬ in.

39. A ¬1 2 h(b1 b2) 1 ¬2(199.8)(57.8 75.6)

2 1 A ¬ 2 bh 3 5 ¬1 2 (5) 2 25 or about 10.8 in2 3 ¬ 4

¬13,326.7 ft2 40. A side length of 20 4 or 5 m and a half-diagonal of 8 2 or 4 m implies that the other halfdiagonal measures 52 42 or 3 m. So d2 2 3 or 6 m. A ¬1 2 d1d2 ¬1 2 (8)(6)

¬24 m2

A

¬1 2 (12)(8 18)

¬8.7 Each side measures about 8.7 ft.

¬7718.6

C5

A ¬1 2 h(b1 b2)

2

12 12 .5 2

2

¬

x

x 10 Let b1 x, b2 x 10, s 2x 3. P ¬b1 b2 2s 52 ¬x (x 10) 2(2x 3) 52 ¬6x 4 48 ¬6x 8 ¬x So b1 8, b2 18, s 13. In order to find the area, we need to find h. Using right triangle ABC, AB s 13, and AC 5. h2 52 ¬132 h2 ¬ 144 h ¬12

2

2

h

5

75 ¬1 2 (12)d2 75 ¬6d2 12.5 ¬d2 Each stone walkway is 12.5 ft long. 37. From Exercise 36, d2 12.5 ft.

d d2 d 2 d 2 2 2 s ¬

13

B

x 2x 3

35. A ¬1 2 bh Solve for h. 300 ¬1 2 (30)h 300 ¬15h 20 ¬h The height is 20 cm. 36. Each rhombus has an area of 150 2 75 ft2. A ¬1 2 d1d2

s2 ¬ 21

12

¬1 2 (24)(10)

44. Because (34.0)2 (81.6)2 (88.4)2, the triangle is a right triangle.

5

5

A ¬1 2 bh

4 5

8

¬1 2 (34.0)(81.6)

5

¬1387.2 m2

391

Chapter 11

2 42 45. LM ¬5 or 3 ft 2 JL ¬(8.5) (4)2 or 7.5 ft JM ¬JL LM ¬3 7.5 ¬10.5 ft A ¬1 2 bh

50. The kite consists of two triangles, each with b 25 in. and h 20 2 or 10 in. A ¬A1 A2 ¬2A1 ¬2(1 2 bh) ¬bh ¬25 10 ¬250 in2 2 51. Comparing heights, 6 3 1. 52. Left triangle Right triangle P 8 8.3 6.5 P 4 4.15 3.25 22.8 11.4 2 2 . 8 2 53. 11.4 1 The ratio is the same. 54. Left triangle Right triangle bh A ¬1 A ¬1 2 2 bh

¬1 2 (10.5)(4) ¬21 ft2 46. A rhombus is made up of two congruent triangles. Using d1 and d2 instead of b and h, its area in 1 1 reference to A 1 2 bh is 2 2 d1 2 d2 or 1 d1d2. 2 47. False; Sample answer: 5 40 3 The area for each of 2 these right triangles is 4 6 6 square units. The perimeter of one triangle is 12 and the perimeter of the other is 8 40 or about 14.3. 48. Drawing the height of an equilateral triangle divides it into two 30°-60°-90° triangles each with base 1 2 b. Left triangle

¬1 ¬1 2 (8)(6) 2 (4)(3) ¬24 ¬6 2 24 4 2 55. 6 1 1 The ratio of the areas is the square of the scale factor. 2 24 4 2 56. 6 1 1 22 .8 2 11.4 1 The ratio of the areas is the square of the ratio of the perimeters. 57. BH ¬6 and HA 3 2 32 BA ¬6 ¬ 45 2 area of ABCD 45 or 45 ft2 area of EFGH 92 81 ft2 45 5 ratio of areas 81 9 or 5:9 58. Sample answer: Umbrellas have triangular panels of fabric or nylon. In order to make the panels to fit the umbrella frame, the area of the triangles is needed. Answers should include the following. • Find the area of a triangle by multiplying the base and the height and dividing by two. • Rhombi are composed of two congruent isosceles triangles, and trapezoids are composed of two triangles and a rectangle. 1 59. B; C is (0, 10), and A 1 2 bh 2 (10)(6) 2 30 units . 60. D; either 2x 7 0 or x 10 0, so either x 7 2 or x 10. 61. Let side b be the base and a be the other given side. Then h asin C. area 1 2 bh

h ¬3 12b ¬3 12(4) ¬23 A ¬1 2 bh ¬1 2 (4)23

¬4 3 or about 6.9 P ¬3(4) 12 Right triangle h ¬3 12b ¬3 12(5) ¬5 2 3 A ¬1 2 bh 5 ¬1 2 (5) 2 3 25 or about 10.8 ¬ 4 3

P 3(5) 15 15 The scale factor and ratio of perimeters is 12 5 or 4. 25 43 The ratio of areas is or 2156, which 4 3 2 5 equals 4 . 49. Left rhombus Right rhombus A ¬1 2 d1d2 ¬1 2 (4)(6)

A ¬1 2 d1d2 ¬1 2 (2)(3)

1 2 absin C

¬12 ¬3 P ¬4213 P ¬413 ¬8 13 The scale factor and ratio of perimeters is 1 4 1 3 2. 3 81 2 3 1 4 , which equals 1 The ratio of areas is 12 2 .

Chapter 11

62. A 1 2 absin C

¬1 2 (4)(7)sin 29° ¬6.79 in2

63. A ¬1 2 absin C

¬1 2 (4)(5)sin 37° ¬6.02 cm2

392

64. A ¬1 2 absin C


¬1 2 (1.9)(2.3)sin 25° ¬0.92 ft2

1.

M y J


4 L

8 4 K

65. A ¬w ¬(22)(17) ¬374 cm2 66. Use a 30°-60°-90° triangle. The height of the parallelogram x3 , where x 12(10) or 5. A ¬bh ¬(15)(5 3) ¬75 3 or about 129.9 in2 67. area ¬area of large rectangle ¬ area of “hanging” rectangle ¬b1h1 b2h2 ¬(21)(9) (6)(7) ¬231 ft2 68. For the circle with center (h, k) and radius r, the equation is (x h)2 (y k)2 r2. Here, (x 1)2 (y 2)2 72, or (x 1)2 (y 2)2 49. 69. For the circle with center (h, k) and radius r, the equation is (x h)2 (y k)2 r2. 2

8

x

4

8

4 8 0 4 4 slope of J K ¬ 4 (8) 4 or 1 8 4 4 M ¬ slope of L 4 0 4 or 1

4 0 4 slope of K L ¬ 0 (4) 4 or 1

8 4 4 M ¬ slope of J 4 (8) 4 or 1

Opposite sides have the same slope and slopes of consecutive sides are negative reciprocals of each other. JK [4 (8)]2 [0 4]2 42 2 KL [0 ( 4)] [4 0]2 4 2 Adjacent sides have the same length. JKLM is a square. 2. Since JKLM is a square with side length 4 2, A s2 (4 2)2 32 units2 3. N P is a horizontal segment with length 4 1 5 so b1 5. M Q is a horizontal segment with length 6 7 13 so b2 13. Since N P and M Q are horizontal, the distance between them, the height, can be measured on any vertical segment. Reading from the graph, h ¬6. A ¬1 2 h(b1 b2)

2

11 Here, [x (4)]2 y 1 2 2 , 2 1 12 1 or (x 4)2 y 2 4.

70. For the circle with center (h, k) and radius r, the equation is (x h)2 (y k)2 r2. Here, [x (1.3)]2 [y 5.6]2 3.52, or (x 1.3)2 (y 5.6)2 12.25. 71. Each semicircle has a radius of 1 2 (3.5) 1.75 in. total inches of trim for one flower 5(r) ¬5(1.75) ¬27.5 in. So she needs 10(27.5) or 275 in. to edge 10 flowers. 72. 136 cos 25°, 136 sin 25° 123.3, 57.5 73. 280 cos 52°, 280 sin 52° 172.4, 220.6 x 74. 46 ¬sin 73° x ¬46 sin 73° ¬44.0 x 75. 30 ¬sin 42° x ¬30 sin 42° ¬20.1

¬1 2 (6)(5 13)

¬54 units2 4. The bases of the trapezoid are vertical segments. b1 WZ 3 (1) 4 and b2 XY 7 1 6 Since W Z and X Y are vertical segments, the distance between them, or the height of the trapezoid, can be measured along any horizontal segment. Reading from the graph, h 5. A ¬1 2 h(b1 b2) ¬1 2 (5)(4 6) ¬25 units2

76. 1 2 (6) ¬3

x 3 ¬tan 58°

5.

x ¬3 tan 58° ¬4.8

A ¬1 2 d1d2 546 ¬1 2 (26)d2

546 ¬13d2 42 ¬d2 d2 is 42 yd long.

393

Chapter 11

4. Side length: Since the perimeter is 108 meters, the 140 10 8 side length is 9 C or 12 m. 40 Apothem: C D is an apothem of the regular nonagon. 20 B The central angles D6 6 are all congruent. A 36 0° The measure of each angle is D 9 or 40°. C bisects ACB so mACD is 20°. AD 6. Write a trigonometric ratio to find the length of C D .

11-3 Areas of Regular Polygons and Circles Page 611

Geometry Activity

1. A 1 2 Pa. Since P (number of sides)(measure of a side), each entry in the last row of the table is 1 2 times the product of the three entries above it.

Number of Sides

3

5

8

10

20

50

6 6 tan 20° CD or CD tan 20° 16.485 m

Measure 1.73r 1.18r 0.77r 0.62r 0.31r 0.126r of a Side Measure of 0.5r 0.81r 0.92r 0.95r 0.99r 0.998r Apothem Area

Area: A ¬1 2 Pa ¬1 2 (108)(16.485) ¬890.2 m2 5. A 30°-60°-90° A triangle is formed by the 60 2.4 cm A cm radius of the 4 2. circle, the 30 C D D apothem, and B B half the base of the equilateral E triangle. A D is the shorter leg, B D is the longer leg, and A B is the hypotenuse. So, AD ¬1 2 2.4 1.2 C B D BD ¬1.2 3 and BC 2.4 3 Next, find the height of the triangle DE. Since mEBD 60, DE 3 BD 3(1.2)( 3) 3.6 shaded area ¬area of circle area of triangle ¬r2 1 2 bh ¬(2.4)2 1 3)(3.6) 2 (2.4 ¬10.6 cm2 6. ABC is a 30°-60°-90° C triangle. A B is the shorter leg and A C is 30 the longer leg. A 60 D AC 3 AB B 3 3 3 3 ADC is also a 30°-60°-90° triangle in E which A C is the shorter leg and A D is the longer leg. So AD 33 3 3 3 9. CE 2 AC because AD is an altitude of CDE 6 3 shaded area ¬area of triangle area of circle 2 ¬1 2 CE AD r

1.30r2 2.39r2 2.83r2 2.95r2 3.07r2 3.14r2

2. The polygon appears to be a circle. 3. The areas of the polygons approach the area of the circle. 4. The formula for the area of a circle is 3.14r2 or r2.

Page 613


1. Sample answer: Separate a hexagon inscribed in a circle into six congruent nonoverlapping isosceles triangles. The area of one triangle is onehalf the product of one side of the hexagon and the apothem of the hexagon. The area of the hexagon is 61 2 sa. The perimeter of the hexagon is 6s, so the formula is 1 2 Pa. 2. Sample answer: Another method besides 30°-60°-90° triangles is to use trigonometric ratios. 3. Side length: Since the perimeter is 42 42 yards, the side length is 6 or 7 yd. 30˚ Apothem: A 30°-60°-90° triangle is formed by the 7 apothem and one-half of a 3.5 side of the hexagon. The shorter leg of the triangle is 1 2 (7) or 3.5. The apothem is the longer leg of the triangle or 3.5 3. Area: A ¬1 2 Pa ¬1 2 (42) 3.53

¬127.3 yd2

¬1 )(9) (3)2 2 (63

¬18.5 in2

Chapter 11

394

12. Since we know that ABC C is a regular triangle, it is equilateral and ADC is a 30°-60°-90° triangle. The 15.5 in. 30 height, C D , of the triangle is the longer leg and A D is the shorter leg.

7. Small cushions Large cushion radius 6 in. radius 10 in. For cloth cover: For cloth cover: r 6 3 9 in. r ¬10 3 13 in. A r2 A ¬r2 2 (9) ¬(13)2 81 ¬169 Area of cloth to cover both sides of all cushions 2(169) 14(81) 1472 in2 To convert to square yards, divide by 1296. 147 2 2 1296 3.6 yd

Pages 613–616

15 .5 AD 2 7.75

CD AD 3 7.753 The area of triangle ABC is

15.5 in.

104.0 in2 13. Apothem: The central angles of the octagon are all congruent so C 36 0 10 mACB 8 or 45°. 45 D C is an apothem of the octagon. It bisects ACB and is a perpendicular A5D B bisector of A B . So mACD 22.5. Since the side of the octagon has measure 10, AD 5. 5 tan 22.5° CD

45

A ¬1 2 Pa

¬1 2 (72)(10.864) ¬391.1 in2 9. side length 842 4 or 212 m A ¬s2 2 ¬21 2 ¬882 m2 (Note: This is easier than finding the central angle, the apothem, and A 1 2 Pa.)

10. ADC is a 45°-45°-90° triangle so AD 12. side length 2 12 24 cm C A s2 2 (24) 45° 576 cm2 12 (Note: This is easier than 45° finding the central angle A D 1 and using A 2Pa.)

B

D

1 1 ) 2AB CD 2(15.5)(7.753

Practice and Apply

8. Side length: 72 8 or 9 in., and 1 2 (9) 4.5 Central angle: 360° 8 or 45°, and 1 4.5 9 2 (45°) 22.5° 4.5 Apothem: tan 22.5° a a 4.5 a tan 2 2.5° 10.864 in.

A

5 CD tan 22.5°

12.07 perimeter 10 8 80 Area: A ¬1 2 Pa ¬1 2 (80)(12.07)

¬482.8 km2 14. square side length 102 shaded area area of circle area of square r2 s2 (10)2 (10 2)2 2 114.2 units 15. Circle radius: 5 2 2.5 shaded area area of rectangle area of circle w r2 (10)(5) (2.5)2 30.4 units2 16. Use 30°-60°-90° triangles. Half the base of the equilateral triangle is 0.75 3, so the base is 1.5 3 and the height is 3(0.75 3) or 2.25. shaded area ¬area of circle area of triangle

B

11. Side length: mACB 60 so mACD 30 and ACD is a 30°-60°-90° triangle. C AD is the shorter leg, so CD 3 AD or 24 24 3 AD. A B D 3 24 3 AD 24 3 83 3 3 So, AB, the side length of the regular hexagon is 2(8 3) 16 3 in. Perimeter: P 6(16 3) 96 3 in.

¬r2 1 2 ab ¬(1.5)2 1 )(2.25) 2 (1.53

¬4.1 units2 17. Use 30°-60°-90° triangles. Half the base of the equilateral triangle is 3.6 3, so the base is 7.23 and the height is 3(3.6 3) or 10.8. shaded area ¬area of triangle area of circle

Area: A ¬1 2Pa ¬1 )(24) 2(963

2 ¬1 2 bh r

¬1995.3 in2

¬1 )(10.8) (3.6)2 2 (7.23

¬26.6 units2

395

Chapter 11

18. The triangle is a 30°-60°-90° right triangle whose sides measure 5, 53 , and 10. Since the hypotenuse of the triangle is a diameter of the circle, and the length of the hypotenuse is twice the length of the shorter leg, the length of the diameter is 10. So the radius of the circle is 5. shaded area ¬area of circle area of triangle

23. The radius of the larger circle is x, while the radius of the smaller circle is 1x. The ratio of 2 areas is x2 x2 2 1 1 2 x 2 x 2 1 1 2

¬r2 1 2 bh

2 1 or 2:1

¬(5)2 1 ) 2 (5)(53

3 24. The scale factor is 9 3 1 , so the ratio of areas 2 9 between a large cake and a mini-cake is 3 1 1. So when nine mini-cakes are compared to one large cake, the total area is equal. Nine minicakes are the same size as one 9-inch cake, but nine mini-cakes cost 9 $4 or $36 while the 9-inch cake is only $15. The 9-inch cake gives more cake for the money. 25. 16-inch pizza 8-inch pizza r8 r4 A 82 A 42 A 64 in.2 A 16 in.2 For 2 pizzas, A 2(16) 32 in.2 One 16-inch pizza; the area of the 16-inch pizza is greater than the area of two 8-inch pizzas, so you get more pizza for the same price. 26. 4

¬56.9 units2 19. Use a 30°-60°-90° triangle. Apothem: The central angle of the regular 36 0° hexagon is 6 60°. The apothem bisects the central angle so it forms a 30° angle with the hypotenuse of the triangle. So the apothem is the longer leg and its measure is 3 21(4.1) 2.05 3. Hexagon perimeter: 6(4.1) 24.6 Radius: The radius of the inscribed circle is the apothem of the regular hexagon. shaded area ¬area of hexagon area of circle 2 ¬1 2 Pa r

¬1 ) (2.053 )2 2 (24.6)(2.053

¬4.1 units2 20. circle radius 1 2 (20) 10 in. Use a 30°-60° -90° triangle. Apothem: The central angle of the regular 36 0° hexagon is 6 60°. The apothem bisects the central angle so it forms a 30° angle with the hypotenuse of the triangle, the radius of the circumscribed circle. So the apothem is the longer leg and has measure 3 1 3 in. 2 (10) 5 Hexagon perimeter: 6(10) 60 in. shaded area ¬area of circle area of hexagon ¬r2 1 2 Pa ¬(10)2 1 3) 2 (60)(5 ¬54.4 in2 21. From the solution to Exercise 14, the outer shaded area is 100 200. The inner circle’s 1 radius is (10) 5 2 and so its area is 2 2 (5 2) 50. shaded area 100 200 50 271.2 units2 22. Use 30°-60°-90° triangles. Half the base of the equilateral triangle is 4 3, so the base is 8 3 and the height is 3(4 3) or 12. Also, the radius of the inner circle is 4. shaded area ¬area of outer circle¬ area of triangle ¬ area of inner circle 2 ¬r21 1 2 bh r2

y

T ( 0, 0) 4

8 4

x

8

4

U ( 7, 7)

8

W ( 7, 7)

12

V ( 0, 14) 16 Explore: Looking at the graph, it appears that quadrilateral TUVW is a square. Plan: Show that TUVW is a parallelogram by showing that T U W V and T U W V . A regular parallelogram is a square. Find the area by using the formula A s2. 7 0 7 Solve: slope of T U 7 0 7 or 1

(14) 7 W 7 slope of V 70 7 or 1

2 TU [0 (7)] [0 (7)]2 72 72 7 2

VW (0 7 )2 [ 14 ( 7)]2 72 72 7 2 TU VW TUVW is a parallelogram. UV (7 0)2 [7 (14 )]2 72 72 7 2 2 The area of the square is s2 (UV)2 7 2 2 98 units . Examine: Another way to find the area of a rhombus is using the formula 1 2 d1d2.

¬(8)2 1 )(12) (4)2 2 (83

¬168.2 units2

A 1 2 (14)(14) 98. The answer is the same.

Chapter 11

396

27. 8

The apothem of the regular octagon is the segment connecting the center (0, 0) with the midpoint of a side. Use the Midpoint Formula to find the midpoint of C B .

y

H ( 0, 4

3 )

4 G ( 12, 0) 1612

x

8 4

x x

4

apothem length

J ( 0, 4

3 )

8

A ¬1 2 Pa

C r 2

34 r 2 17

A ¬1 2 bh

A ¬r2 ¬(17)2 ¬289 or about 907.9 units2 31. C ¬2r

¬1 (12) 2 83

¬483 or about 83.1 units2

4

y

QX

M

C r ¬ 2

R

17 17 r ¬ 2 2

x

N 8 4

A ¬r2

4 J 8 4 8 L

K

28 9 2 ¬ 4 or about 227.0 units

32. C ¬2r C r ¬ 2

y y 2

54 .8 27 .4 r ¬ 2

A ¬r2

750 .76 ¬ or about 239.0 units2

33. C ¬2r

A

2

2

45 .7 ¬

2088.49 2 ¬ or about 664.8 units

¬21649 or about 81.2 y B X

45 .7 91 .4 r ¬ 2 A ¬r2

9 97 0)

2 0 2 (2

2

A ¬1 2 Pa 97 ¬1 ) 2 2 (817

29.

C r ¬ 2

M2, 9 2

apothem length

34. units2

A ¬r2 7850 ¬r2

5 3 14 7850 r ¬ C ¬2r 53 14 ¬2 ¬10 314 or about 314.1 ft

C x

H

2

27 .4 ¬

04 54 1 1 M 2 , 2 M2, 2

2

1 7 ¬ 2

The figure is a regular octagon centered at the origin. 2 (4 side length QR (4 0) 5)2 17, so perimeter 8 17 The apothem of the regular octagon is the segment connecting the center (0, 0) with the midpoint of a side. Use the Midpoint Formula to find the midpoint of Q R . x x 2

2

30. C 2r

h 0 (12) 12 or 12

P

2

¬4145 or about 48.2 units2

HJ 43 43 8 3 or 83

8

3 0 7 0 2 2

258

58 ¬1 ) 2 2 (810

J H is vertical.

28.

y y

3 3 0 4 1 2 1 2 3 7 M 2 , 2 M 2 , 2 M 2 , 2

D

At 2 tiles per foot, and rounding up, that makes 629 tiles. 35. The square tiles will touch along the inner edge of the border, but there will be gaps along the outer edge. The tiles used to fill the gaps should be triangles. There will be 629 gaps between the 629 square tiles, so 629 triangular tiles will be needed.

E F The figure is a regular octagon centered at the origin. side length BC (3 0 )2 (3 4)2 10, so perimeter 8 10 G

397

Chapter 11

36. A ¬r2 ¬(1.3)2 ¬1.69 or about 5.3 cm2 37. Use radius 11 in. A r2 (11)2 121 or about 380.1 in2 38. Sample answer: Multiply the total area by 40%. 39. Use a 30°-60°-90° triangle. For the equilateral triangle, the height is opposite the 60° angle so it is the longer leg of the 30°-60°-90° triangle with hypotenuse measure of 3. So, height 3 1 2 (3) 3 2 3. For the circle, radius 1 2 (7) 3.5. shaded area ¬area of circle area of triangle

45. The area of the garden equals that of a square of side length 175 ft combined with a circle of radius 1(175) or 87.5 ft. 2 area s2 r2 (175)2 (87.5)2 7656.25 30,625 54,677.8 ft2 The perimeter is the circle’s circumference plus two side lengths from the square. perimeter 2r 2s 2(87.5) 2(175) 175 350 899.8 ft 46. d1 d2 d3 20 40 60 120 or about 377.0 ft 47. The path is defined by an outer circle of radius 1(60) 5 25 and an inner circle of radius 2

¬r2 1 2 bh

1(40) 20. 2

3 ¬(3.5)2 1 2 (3) 2 3 ¬12.25 9 4 3

path area area of outer circle area of inner circle r12 r22 (25)2 (20)2 225 or about 706.9 ft2 48. No; the areas of the floors will increase by the squares of 1, 3, 5, and 7, or 1, 9, 25, and 49. The ratio of the areas is the square of the scale factor.

¬34.6 units2 40. circle diameter 122 92 15, and radius 1(15) 7.5. 2 shaded area area of circle area of rectangle r2 w (7.5)2 (9)(12) 56.25 108 68.7 units2 41. r1 large radius 10, r2 small radius 5 shaded area ¬area of large circle ¬¬area of small circles ¬r21 2r22 ¬(10)2 2(5)2 ¬50 or about 157.1 units2 42. circle radii 1.5 shaded area area of square area of circles s2 4r2 (6)2 4(1.5)2 36 9 7.7 units2 43. Flip the right half top-forbottom, to make it a mirror image of the left half. Then r1 there are three circles, with radii of r1 15, r2 10, and r3 5. r2 r3 shaded area ¬area of large circle area of medium circle area of small circle ¬r21 r22 r23 ¬(15)2 (10)2 (5)2 ¬150 or about 471.2 units2 44. The large semicircle has radius r1 7.5, the small semicircles have radii r2 2.5. shaded area ¬area of large semicircle ¬ area of small semicircles

4. 2 2 49. 6.3 3 or 2 : 3

50. Call the perimeter of the figure on the left P1 and the figure on the right P2. P1 5(4.2) or 21 cm P2 5(6.3) or 31.5 cm 21 2 51. 31 .5 3 The ratio is the same. 52. Using the perimeter information from Exercise 50, A1 ¬1 2 Pa

¬1 2 (21)(2.88) ¬30.24 cm2

A2 ¬1 2 Pa

¬1 2 (31.5)(4.32) ¬68.04 cm2

2 30. 24 4 2 53. 68.04 9 3

The ratio of the areas is the square of the scale factor. 2 30. 24 4 2 54. 68.04 9 3

21 2 31 .5 3

The ratio of the areas is the square of the ratio of the perimeters. 55. The apothem of the larger hexagon equals the radius of the circle, r 10. The apothem of the 3 r. 1r smaller hexagon is 3 2

2 ¬2r12 3 1 2 r2

1

2 2 1 ¬1 2 [(7.5) ] 3 2 [(2.5) ]

¬18.75 or about 58.9 units2

Chapter 11

398

2

3

2r 3 scale factor r 2 area ratio ¬(scale factor)2 3 2 ¬

ABCD is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. A ¬bh ¬(7)(3) ¬21 units2

10

2 3 ¬4 or a ratio of 3 to 4

(The value of r is irrelevant.) 63.

56. Sample answer: You can find the areas of regular polygons by finding the product of the perimeter and the apothem and then multiplying by one half. Answers should include the following. • We need to know the length of each side and the length of the apothem. • One method is to divide the area of the floor by the area of each tile. Since the floor is hexagonal and not rectangular, tiles of different shapes will need to be ordered to cover the floor. 57. B; for the circle, A r2 so that r 32 . Square side length s 2 r

J ( 2, 1)

F ( 4, 1) x

H ( 2, 5)

18 A

slope of slope of

2 (32 ) 6 units.

slope of

58. B; since average sum x, x sum average 90 15 6.

Page 616

y

slope of

G ( 4, 5)

11 0 J F 4 (2) 6 or 0 5 (5) 0 G H 4 (2) 6 or 0 1 (5) 6 J H 2 (2) 0 is undefined 5) 1 ( 6 F G 4 4 0 is undefined

FGHJ is a square, since the sides are all equal and are all horizontal or vertical. A ¬s2 ¬(6)2 ¬36 units2


59. A ¬1 2 d1d2 1 ¬2(20)(26)

64.

¬260 cm2

L ( 2, 5)

y M ( 1, 5)

60. area ¬area of upper triangle ¬ area of lower triangle 1 ¬1 2 bh1 2 bh2

x

1 ¬1 2 (16)(7) 2 (16)(6)

¬104 m2 61. Use a 30°-60°-90° triangle. Base 1(70) yd. 3 A ¬bh

K ( 1, 3)

¬170(70) 3 ¬2829.0 yd2 62.

3 (3)

0 or 0 slope of K N 3 2 (1) 55

0 M slope of L 1 (2) 3 or 0

y

3 5

8 K slope of L 1 (2) 1 or 8 3 5

8 N slope of M 2 1 1 or 8

B ( 4, 2)

A ( 3, 2)

KLMN is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. A bh (3)(8) 24 units2

x

D ( 5, 1)

N ( 2, 3)

C ( 2, 1)

22

0 slope of A B 4 (3) 7 or 0 1 (1)

0 C slope of D 2 (5) 7 or 0 2 (1)

3 A slope of D 3 (5) 2 2 (1)

3 slope of C B 42 2

399

Chapter 11

65.

1 2 ¬1 2 b1h b2h 2 r

y

2 1 ¬1 2 (2)(4) 2 4 2 (2)

¬4 8 2 ¬18.3 units2

x

R ( 1, 2)

S ( 5, 2)

Q ( 1, 7)

P ( 5, 7)

y

h

r x

b1

O

b2

7 (7)

0 slope of Q P 5 (1) 6 or 0 2 (2)

0 slope of R S 5 (1) 6 or 0

2. An irregular polygon is a polygon in which all sides are not congruent. If a shape can be separated into semicircles or smaller circular regions, it is an irregular figure. 3. area ¬area of rectangle area of triangle ¬w 1 2 bh ¬(9.2)(3.6) 1 2 (9.2)(8 3.6) ¬53.36 or about 53.4 units2 4. area ¬area of rectangle area of semicircle 2 ¬w 1 2 r 2 ¬(32)(16) 1 2 (8) ¬512 32 or about 612.5 units2 5. area of MNPQ ¬area of MNQ area of QNP

2 (7) 5 slope of Q R 1 (1) 0 is undefined 2 (7) 5 is undefined slope of P S 0 55

PQRS is a rectangle, since the sides are not all equal but are all horizontal or vertical. A w (6)(5) 30 units2 66. HE ¬1 2 (CD GF) 38 ¬1 2 (46 GF)

76 ¬46 GF 30 ¬GF

1 ¬1 2 bh1 2 bh2

67. WX ¬1 2 (CD HE)

1 ¬1 2 (6)(5) 2 (6)(3)

¬1 2 (46 38)

¬24 units2 6. area ¬area of rectangle¬ combined area of two semicircles ¬w r2 ¬(10)(4) (2)2 ¬40 4 or about 52.6 units2

¬42 68. Use GF 30 from Exercise 66. YZ ¬1 2 (HE GF) ¬1 2 (38 30)

¬34 69. h is opposite the 30° angle of a 30°-60°-90° triangle, so h 1 2 (12) 6. 70. h is adjacent to the 30° angle of a 30°-60°-90° triangle, so h 3 15 15 3. 71. h is one leg of a 45°-45°-90° triangle, so h 1 8 4 2. 2 72. h is one leg of a 45°-45°-90° triangle, so 21 2 . h 1 21 2 2

7. The height of the triangular portion is given by h

¬w 1 2 bh ¬(41.6)(24) 1 6 ) 2 (41.6)(143.3

¬1247.4 in2

Pages 619–621

Practice and Apply

8. Notice that the triangle that is cut out on the left is congruent to the triangle added on the right. area ¬area of rectangle area of triangle area of triangle ¬area of rectangle ¬w ¬(10)(5) ¬50 units2


1. Sample answer: Area of irregular figure ¬area of triangle area of rectangle area of semi-circle

Chapter 11

2

2

area ¬area of rectangle area of triangle

11-4 Areas of Irregular Figures Page 619

41 .6 6 . (24)

2 143.3

400

9. area area of rectangle area of semicircle 2 ¬w 1 2 r

19.

2 ¬(8)(12) 1 2 (4) ¬96 8 or about 70.9 units2 10. area area of rectangle area of triangle

y

P ( 5, 3)

N ( 0, 3)

¬w1 1 2 bh

M ( 4, 0)

Q ( 5, 0)

x

¬(12)(25) 1 2 (10)(8)

¬340 units2 11. area area of rectangle area of triangle

area of trapezoid ¬1 2 h(b1 b2)

¬w1 1 2 bh

¬1 2 (3)(5 9)

¬(62)(54) 1 2 (62)(27)

¬21 units2

¬4185 units2 12. area 2 area of one trapezoid

20.

y

¬2 1 2 h(b1 b2)

U ( 2, 2)

¬h(b1 b2) ¬10(8 23) ¬310 units2 13. area ¬area of rectangle combined area of two semicircles ¬w r2 ¬(22)(14) (7)2 ¬308 49 or about 154.1 units2 14. The semicircle has radius 18 in. The perimeter is 48 36 48 18 132 18 or about 188.5 in. 15. area ¬area of rectangle area of semicircle

b2

x

T ( 4, 2)

b1 W ( 3, 2)

area ¬area of triangle area of trapezoid 1 ¬1 2 b2h2 2 h1(b1 b2) 1 ¬1 2 (5)(2) 2 (4)(7 5) ¬29 units2

2 ¬w 1 2 r 2 ¬(36)(48) 1 2 (18)

21.

¬1728 162 or about 2236.9 in2 16. area ¬area of square combined area of two triangles ¬s2 2 1 2 bh ¬s2 bh ¬(4)2 (4)(2) ¬24 units2 17. area ¬area of triangle area of semicircle

y

b1 G ( 3, 1)

I ( 2, 4)

h2 b4 b2

H ( 3, 1) h1

h3 b3

x

J ( 5, 1)

K ( 1, 3)

1 2 ¬1 2 bh 2 r 2 1 ¬1 2 (6)(3) 2 (3)

¬9 4.5 or about 23.1

V ( 3, 4) h2 ( 3, 2) h1

area ¬area of trapezoid area of upper triangle area of lower triangle 1 1 ¬1 2 h1(b1 b2) 2 b3h2 2 b4h3

units2

18. area ¬area of rectangle area of semicircle area of semicircle ¬area of rectangle ¬w ¬(5)(4) ¬20 units2

1 1 ¬1 2 (5)(2 5) 2 (3)(5) 2 (8)(2)

¬33 units2

401

Chapter 11

22. 12

P ( 8, 7) h1

8

b1 b2 h3 S ( 1, 3) 4 T ( 11, 1) 12 8 4 4

34. Hexagon side length 16, and perimeter 6 16 96. Use a 30°-60°-90° triangle to find the apothem ¬x 3 where x 1 2 (16) 8. area ¬area of circle area of hexagon

y

h2 Q ( 3, 7)

¬r2 1 2 Pa

b3 x

¬(16)2 1 ) 2 (96)(83

4 R ( 3, 2)

¬256 3843 or about 139.1 units2 35. Use a 30°-60°-90° triangle. Base 1 3 (57) 19 ft.

where x 12(19) 9.5 ft. Height x3

A ¬1 2 bh

area ¬area of left trapezoid area of right trapezoid area of triangle 1 1 ¬1 2 h1(b1 b2) 2 h2(b1 b3) 2 b2h3

¬1 ) 2 (19)(9.53

¬90.253 or about 156.3 ft2 36. The area of the rhombus is divided into four congruent right triangles with hypotenuse

1 1 ¬1 2 (10)(4 6) 2 (4)(4 9) 2 (6)(3)

23. 24. 25. 26.

27. 28.

¬67 units2 Sample answer: (23 squares)(2500 mi2 per square) 57,500 mi2 See students’ work. Add the areas of the rectangles. 6 22 6 20 6 16 6 11 6 8 462 The actual area of the irregular region should be smaller than the estimate. The rectangles drawn are larger than the region. Sample answer: Reduce the width of each rectangle. 3 x. Let BC x. Then the altitude of the triangle is 3 1(x) 2 x 2

10 6

length 10 yd and one side length 6 yd. The other 2 side length is 10 62 8. So the two diagonals measure 12 yd and 2(8) 16 yd. A ¬1 2 d1d2

2

¬1 3 3 2 bh area of ABC ¬4 or 4 : 1 area of BCDE x2 s2

¬1 2 (12)(16)

¬96 yd2 37. Let the shorter base b1 x. Then b2 2x 5 and P 90 x (2x 5) 2(x 3) 5x 11 5x 11 ¬90 5x ¬101 x ¬20.2

29. Sample answer: Windsurfers use the area of the sail to catch the wind and stay afloat on the water. Answers should include the following. • To find the area of the sail, separate it into shapes. Then find the area of each shape. The sum of areas is the area of the sail. • Sample answer: Surfboards and sailboards are also irregular figures. 30. B; let LM x. Then, starting at the bottom and moving clockwise, P 7x 4x 4x 2x 2x x x x 22x. So 22x 66 and x LM 3. area ¬area of A area of B area of C ¬s12 s22 s32 ¬(12)2 (6)2 (3)2 ¬189 units2 31. C; 16 92 4 81 85

Page 621

A ¬1 2 h (b1 b2) ¬1 2 15 (x 2x 5) ¬1 2 15 (20.2 40.4 5) 7.5(55.6)

¬417 m2 38. The image of the point lies in quadrant IV, 6 units 1 away from the origin, at (x, y) 1 6, 6 2 2 (3 2, 3 2). 39.


32. area ¬area of square area of circle ¬s2 r2 ¬(14)2 (7)2 ¬196 49 or about 42.1 units2 33. area ¬area of circle area of triangle ¬r2 1 2 bh

2

¬ 12 1 2 (12)(12) 2 ¬72 72 or about 154.2 units2 1

Chapter 11

402

0.625 85 .0 0 0 4.8 20 16 40 40 0 0.63. So 5 8

40.

41.

42.

3. Use a 30°-60°-90° triangle. Half the base of the triangle is 42, so the apothem, which is also the

0.8125 3 .0 0 0 0 161 12.8 20 16 40 32 80 80 0 13 0.81. So 16

143 . radius of the circle is 42 3 Triangle perimeter 3(84) 252 shaded area ¬area of triangle area of circle 2 ¬1 2 Pa r 2

1 143 2 (252)143

¬17643 588 or about 1208.1 units2 4. pentagon central angle 360° 5 or 72°, and

0.191... 479 .0 0 0 4.7 4.30 4.23 70 47 23 9 So 47 0.19.

1 2(72°) 36°.

half side length 21 tan 36°, and side length 42 tan 36°, so perimeter 5(42 tan 36°) 210 tan 36° 152.574. shaded area ¬area of pentagon area of circle 2 ¬1 2 Pa r 2 ¬1 2 (152.574)(21) (21)

¬216.6 units2

0.476... 211 0 .0 0 0 8.4 1.60 1.47 130 126 4

5.

y

8

D ( 1, 3) 4

G ( 5, 5) h3 H ( 8, 3) b 2

x h1 4 8 4 h8 C ( 3, 2)4 b 1 ( 2 ) J 5, 2

10 So 21 0.48.

8

Page 621

Practice Quiz 2 area ¬area of left triangle area of middle triangle area of upper triangle

1.

1 1 ¬1 2 b1h1 2 b2h2 2 b2h3 1 1 ¬1 2 (8)(5) 2 (7)(5) 2 (7)(2) 30

¬44.5 units2 14

60

, and side length 2 14 ¬28 3 3 563 perimeter ¬6 28 3 Pa A ¬1 2

11-5 Geometric Probability Page 625 Check for Understanding 1. Multiply the measure of the central angle of the sector by the area of the circle and then divide the product by 360°. 2. Sample answer: darts, archery, shuffleboard 62 3. Rachel; Taimi did not multiply 36 0 by the area of the circle.

¬1 (14) 2 563

¬3923 or about 679.0 mm2 2. side length 72 8 or 9 in., and 1 2 (9) 4.5 central angle 360° 8 or 45°, and 1 2 (45°) 22.5°.

N

r2 4. A ¬ 360 80 2 ¬ 36 0 (5 )

22.5

4.5 apothem tan 2 2.5°

10.864 in. A ¬1 2 Pa ¬1 2 (72)(10.864)

50

¬9 or about 17.5 units2 blue area

9

P(blue) ¬ area o f circle 5 0

9 ¬ 2 9 or about 0.22 (52)

¬391.1 in2

403

Chapter 11

N 2 15. A ¬ 360 r 80 72 ¬ (7.52) 360

5. short side of one triangle 10, 1 so area of square 4 1 2 bh 4 2 (10)(10) or 200 area of circle r2 102 100 blue area ¬area of circle area of square ¬100 200 or about 114.2 units2

¬23.75 or about 74.6 units2 yellow area

P(yellow) ¬ area of circle 23.75 ¬ 2

blue area P(blue) ¬ area of circle 100 200 ¬ 100

(7.5 )

¬0.42 16. Using A r2, we find that the smallest circle encloses yd2, the medium circle 4 yd2, and the large circle 9 yd2. shaded area 9 4 6 yd2

2 ¬1 or about 0.36

6. 60 out of 100 squares are shaded. 60 3 P(shaded) 10 0 5 or 0.6

Pages 625–627

shaded area P(shaded) ¬ overall area 6 2 ¬ 9 or 3

Practice and Apply

7. 60 out of 100 squares are shaded. 60 P(shaded) 10 0 0.60 8. 50 out of 100 squares are shaded. 50 P(shaded) 10 0 0.50 9. 54 out of 100 squares are shaded. 54 P(shaded) 10 0 0.54

N 2 17. area of sector ¬ 360 r 6 0 2 ¬ 360 (6 )

¬6 Use a 30°-60°-90° triangle, with the length of the short leg 1 . 2 (6) 3 so that apothem 33 1 area of triangle ¬2bh

N 2 10. A ¬ r 360

¬1 2 (6)33 ¬93 area of segment area of sector area of triangle 6 9 3 or about 3.3 units2

72 2 ¬ 36 0 (7.5 )

¬11.25 or about 35.3 units2 area of sector P(blue) ¬ area of circle 11.2 5 ¬ (7.52)

area of segment

P(shaded) ¬ area of circle 93 6 ¬ 2

¬0.20

N

2 11. A ¬ 360 r 60 60 ¬ 7.52 360

(6 ) 3 1 ¬6 4 or about 0.03 N 2 18. area of sector ¬ 360 r 12 0 2 ¬ 360 (8 ) 64 ¬ B 3

18.75 or about 58.9 units2 18.7 5 P(pink) ¬ (7.52) 1 3 or about 0.33 N r2 12. A ¬ 360 5 45 45 4 ¬ (7.52) 360

Use a 30°-60°-90° triangle, with apothem 1 2 (8) 4.

area of ABC ¬1 2 bh 1 ¬2(2 43 )(4) ¬16 3 area of segment ¬area of sector ¬ area of triangle 64 ¬ 3 or 3 16 ¬about 39.3 units2

66.3 units2

purple area

P(purple) ¬ area of circle 6 6 . 3 ¬ 2 (7.5 )

¬0.375 N 2 13. A ¬ r 360 40 2 ¬ 36 0 (7.5 )

16

C

area of segment

P(shaded) area of circle

¬6.25 or about 19.6 units2

64

red area P(red) ¬ area o f circle

163 3 2

(8 )

6.25

¬ (7 .52)

3 ¬1 3 4 or about 0.20 N 2 19. area of sector 360 r

¬1 9 or about 0.11 N 2 14. A ¬ r 360 58 60 55 (7.52) 36 0

7 2 2 360 (7.5 )

11.25 The five central angles of the pentagon each 36 0° measure 5 or 72°. Let s pentagon side length and a apothem.

¬84.9 units2 green area

P(green) ¬ area of circle 84 .9 ¬ (7.52) ¬0.48

Chapter 11

A

404

72° s 7.5 sin 2 2 s 15 sin 36° 72° 7.5 cos 2 a a 7.5 cos 36° area of triangle ¬1 2 bh 1 ¬2sa

In Exercises 26–28, the overall area is (72) 49 units2. Also, red area ¬ 12 ( 42 32) ( 72 62) ¬21 units2 white area ¬1 2 (overall area red area) 1 ¬2(49 21)

¬1 2 (15 sin 36°)(7.5 cos 36°) ¬26.7 area of segment ¬area of sector ¬ ¬ area of triangle ¬11.25 26.7 ¬8.6 shaded area ¬3(area of segment) ¬25.8 shaded area P(shaded) ¬ area of circle

¬14 units2 black area ¬white area ¬14 units2 black area

26. P(black) ¬ overall area 14

¬ 49 2

¬7 or about 0.29 white area 27. P(white) ¬ overall area 14 ¬ 49

25 .8 ¬ (7.52)

2

¬7 or about 0.29

¬0.15

red area

28. P(red) ¬ overall area 21 ¬ 49

In Exercises 20–23, area of region

probability ¬ area of circle total angle in region

3

¬7 or about 0.43

¬ . 360°

29. The chances of landing on a black or white sector are the same, so they should have the same point value. 30. Of the three colors, there is the highest probability of landing on red, so red should have a lower point value than white or black. 31a. No; each colored sector has a different central angle. 31b. No; there is not an equal chance of landing on each color. 32. Sample answer: Geometric probability can help you determine the chance of a dart landing on the bullseye or high scoring sector. Answers should include the following. • Find the area of the circles containing the red sector. Divide the difference by the area of the larger circle. • Find the area of the center circle and divide by the area of the largest circle on the board. 33. C; total area ¬area of square area of semicircle

28. 8° 20. P(red) 360° ¬0.08 97.2° 147.6° 21. P(blue or green) ¬ 0.68 360°

22. P(not red or blue) ¬1 P(red or blue) 147.6° 28.8° ¬1 360°

¬0.51 23. P(not orange or green) 1 P(orange or green) 97.2° 18° ¬1 360°

¬0.68 24. court area w ¬(39)(39) ¬1521 ft2

27 39 out-of-bound lane width ¬ ¬6 ft 2

out-of-bounds area ¬w w ¬6 39 6 39 ¬468 ft2 out-of-bounds area probability court area 468 ¬ 15 21

2 ¬s2 1 2 r

4 ¬ 1 3 or about 0.31 27 25. service box width ¬ 2 13.5 ft

2 ¬52 1 2 (2.5 )

¬34.8 shaded area ¬area of square area of semicircle 2 ¬52 1 2 (2.5 ) ¬15.2

service box area ¬1w1 ¬(13.5)(21) ¬283.5 ft2 court area ¬2w2 ¬(39)(39) ¬1521 ft2

shaded area P(shaded) total area 15 .2 ¬ 34.8 ¬0.44

service box area probability court area

34. C; y 16 4 4, so 12 y 12 4 3.

283 .5 ¬ 1521 ¬0.19

405

Chapter 11

35. area area of rectangle area of left triangle ¬ area of upper triangle 1 ¬w 1 2 b1h1 2 b2h2

45. Use the Law of Cosines, with a g, b 32, c 29, and A ¬41. a2 ¬b2 c2 2bc cos A g2 ¬322 292 2(32)(29) cos 41° g2 ¬1865 1856 cos 41° g ¬1865 cos 1856 ° 41 g ¬21.5

1 ¬(28)(20) 1 2 (16)(35) 2 (28)(15) ¬1050 units2 36. area area of rectangle area of semicircle 2 w 1 2 r 2 (12)(9) 1 2 (4) 108 8 or about 82.9 ft2


37. Side length 1 3 (48) 16 ft. Use a 30°-60°-90° triangle. Height x3 where x 12(16) 8 ft. A ¬1 2 bh ¬1 2 (16)83

Pages 628–630 1. c 2. e 3. a

¬643 or about 110.9 ft2 2 38. A ¬s ¬(21)2 ¬441 cm2 39. Use a 30°-60°-90° triangle. 1 1 Half side length ¬(8), side length ¬(16), 3 1 in. perimeter ¬6 (16) 323 3 1 A ¬2Pa

4. f 5. b 6. d 7. P 2(23) 2(16) 78 ft Use a 30°-60°-90° triangle to find the height, with x as the length of the shorter leg. 16 ¬2x 8 ¬x height ¬x3 ¬83 ft A ¬bh ¬(23)(83 ) ¬1843 or about 318.7 ft2 8. P ¬2(36) 2(22) ¬116 mm Use a 30°-60°-90° triangle to find the height, with x as the length of the shorter leg. 22 ¬22x 11 ¬x ¬height A ¬bh ¬(36)(11) ¬396 mm2 9. y

3

1

¬2(323 )(8) 40.

41.

42.

43.

44.

¬1283 or about 221.7 in2 mAFB mBFC ¬180 mAFB 72 ¬180 mAFB ¬108 mCFD mAFD ¬180 (4a 1) (2a 5) ¬180 6a 6 ¬180 6a ¬186 a ¬31 mCFD ¬4a 1 ¬4(31) 1 ¬123 mCFD mAFD ¬180 (4a 1) (2a 5) ¬180 6a 6 ¬180 6a ¬186 a ¬31 mAFD ¬2a 5 ¬2(31) 5 ¬57 From Exercises 40 and 42, mAFB ¬108 and mAFD ¬57. mDFB ¬mAFB mAFD ¬108 57 ¬165 Use the Law of Cosines, with a ¬p, b 6.8, c 11.1, and A ¬57. a2 ¬b2 c2 2bc cos A p2 ¬6.82 11.12 2(6.8)(11.1)cos 57° p2 ¬169.45 150.96 cos 57° p ¬169.4 5 0.96 15os c 57° p ¬9.3

Chapter 11

A ( 6, 1)

B ( 1, 1) x

D ( 6, 6) ABCD is a square. A ¬s2 ¬72 ¬49 units2

406

C ( 1, 6)

10.

3 1 4 slope of R S ¬ 5 (1) or 1

y

3 (1)

G ( 2, 2)

H ( 8, 2)

PQRS is a rectangle, since opposite sides have the same slope and the slopes of consecutive sides are negative reciprocals of each other. Length of S R ¬[1 (5)]2 [1)] (32 ¬42 Length of Q R ¬[1 (3)]2 [1 3]2 22 PQRS is not a square since not all sides have the same length. A ¬w ¬(42 )(22 ) ¬16 units2

x

E ( 7, 2)

F ( 1, 2)

2 (2)

4 slope of F G ¬ 2 1 1 or 4 2 (2)

4 H ¬ slope of E 8 7 1 or 4 2 (2)

E ¬ 0 slope of F 7 1 6 or 0

2 2 0 H ¬ slope of G 8 2 6 or 0

L(5, 5)

A ¬1 2 bh

13.

336 ¬1 2 b(24) 336 ¬12b 28 ¬b base ¬CE 28 in.

EFGH is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. A ¬bh ¬6 4 ¬24 units2 11.

4

2 S ¬ slope of P 5 (7) 2 or 1 13 2 R ¬ slope of Q 1 (3) 2 or 1

14. A ¬1 2 h(b1 b2)

75 ¬1 2 h(17 13) 75 ¬15h 5 ¬h The height is 5 m.

y

15. M (1, 1)

20

x

K ( 5, 0)

36 10

J ( 1, 4)

side length 100 5 20, and 1 2 (20) 10 central angle 360 5 72°, and 1 2 (72°) 36° 10 apothem tan 36° 13.764 A ¬1 2 Pa

0 (4)

4 slope of J K ¬ 5 (1) 4 or 1

15 4 M ¬ slope of L 1 (5) 4 or 1 1 (4)

5 M ¬ slope of J 1 (1) 0 undefined

¬1 2 (100)(13.764) ¬688.2 in2

5 0 5 L ¬ slope of K 5 (5) 0 undefined

JKLM is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle.

16. 12

A ¬bh ¬4 5 ¬20 units2

18

6

12.

y

half side length 1 2 (12) 6 mm perimeter 10 12 120 mm central angle 360° 10 36°, and 1 2 (36°) 18° 6 apothem 18.466 tan 18°

Q (3, 3) R (1, 1) x

A ¬1 2 Pa

¬1 2 (120)(18.466) ¬1108.0 mm2

P ( 7, 1) S ( 5, 3) 3 (1)

4 slope of P Q ¬ 3 (7) 4 or 1

407

Chapter 11

17. area ¬area of rectangle ¬ combined area of two semicircles ¬w r2 ¬(8)(3) (1.5)2 ¬24 2.25 or about 31.1 units2 18. For the height of the trapezoid, use a 30°-60°-90° triangle: x 4, so h 43 . area ¬area of trapezoid area of semicircle 1 2 ¬1 2 h(b1 b2) 2 r

5.

T(5, 5)

y

S (9, 3) U (3, 1) x

R (7, 1)

2 ¬1 )(8 10) 1 2 (43 2 (4) ¬363 8 or about 87.5 units2

1 2 1 1 slope of U R ¬ 7 3 ¬ 4 or 2 2 3 5 1 slope of T S ¬ 9 5 ¬ 4 or 2

N 2 19. A ¬ r 360 12 0 2 ¬ 360 (6 )

5 1 4 slope of U T ¬ 5 3 ¬ 2 or 2 1) 3 ( 4 S ¬ slope of R 9 7 ¬ 2 or 2 RSTU is a rectangle, since opposite sides have the same slope and the slopes of consecutive sides are negative reciprocals of each other. 2 (5 Length of U T ¬(5 ) 3 1)2 25 2 ( Length of U R ¬(7 ) 31 1)2 25 Thus RSTU is in fact a square. A ¬s2 ¬(25 )2 ¬20 units2

¬12 red area P(red) ¬ area of circle 12 ¬ (62)

¬1 3 or about 0.33 N 2 20. A ¬ r 360

60 36 2 ¬ 360 (6 )

¬9.6 purple or green area

P(purple or green) ¬ area of circle 9.6 ¬ (62)

6.

4 ¬ 1 5 or about 0.27

y

S ( 4, 5)

T ( 7, 5)

Chapter 11 Practice Test R ( 2, 0) U ( 5, 0)

Page 631 1. a 2. c 3. b 4. R(6, 8)

x

0 0 0 slope of R U ¬ 5 2 3 or 0

y

5 5 0 T ¬ slope of S 7 4 3 or 0 5 0 5 T ¬ slope of U 75 2 5 0 5 slope of R S ¬ 42 2

S(1, 5) U (6, 4) T (1, 1)

RSTU is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. A ¬bh ¬(3)(5) ¬15 units2

x

14 3 3 slope of U T ¬ 1 (6) 5 or 5

58 3 3 slope of R S ¬ 1 (6) 5 or 5 84 4 slope of U R ¬ 6 (6) 0 is undefined

51 4 S ¬ slope of T 1 (1) 0 is undefined RSTU is a parallelogram, since opposite sides have the same slope. Slopes of consecutive sides are not negative reciprocals of each other, so the parallelogram is neither a square nor a rectangle. A ¬bh ¬(5)(4) ¬20 units2

Chapter 11

408

7.

N 2 13. A ¬ 360 r

y

60 40 2 ¬ 360 (6 ) ¬10

8

S ( 9, 3)

4 8 4

red a rea P(red) ¬ area of circle 10 ¬ 2

T ( 12, 1)

4

(6 )

x

5 ¬ 18 or about 0.28

R ( 3, 6) 8

N 2 14. A 360 r 8 6 2 ¬ 360 (6 )

U ( 6, 8)

¬8.6

2 8 (6) 2 slope of R U ¬ 3 or 3 63 2 13 2 slope of S T ¬ 12 9 3 or 3

orange area

P(orange) ¬ area of circle 8. 6 ¬ (62)

6) 3 ( 9 3 slope of R S ¬ 9 3 6 or 2 8) 1 ( 9 3 slope of U T ¬ 12 6 6 or 2

¬0.24 N 2 15. A¬¬ r 360 45 35 55 (62) ¬ 360

RSTU is a rectangle, since opposite sides have the same slope and the slopes of consecutive sides are negative reciprocals of each other. 2 [6)] Length of R U [6 ] 38 (2 13 2 Length of R S [9 ] 3 [3)] (62 313 RSTU is not a square since not all sides have the same length. A w (13 )(313 ) 39 units2 8. area ¬area of left triangle area of right triangle

¬13.5 green area P(green) ¬ area of circle 13. 5 ¬ (62)

¬3 8 or about 0.38

16. area ¬area of trapezoid area of parallelogram ¬1 2 h(b1 b2) b1h2 ¬1 2 (8)(21 24) (21)(14)

¬474 units2 17. triangle height x3 , where x 1 2 (6) 3 area area of rectangles area of triangles ¬2w 2 1 2 bh

1 ¬1 2 b1h1 2 b2h2 1 ¬1 2 (17)(6) 2 (28)(15)

¬261 m2 9. area ¬area of rectangle area of triangle ¬w 1 2 bh ¬(39)(18) 1 2 (56 39)(18) ¬855 yd2

¬2(6)(5) 2 1 ) 2 (6)(33

¬60 183 or about 91.2 units2 18. area ¬area of square ¬ combined area of semicircles 2 ¬s2 2 1 2 r 2 ¬(7) (3.5)2 ¬49 12.25 or about 87.5 units2

10. area ¬1 2 h(b1b2) ¬1 2 (22)[32 (3 32 7)]

¬814 cm2 11. octagon central angle 360° 8 45°, and 1(45°) 22.5° 2 half side length 3 tan 22.5°, and side length 6 tan 22.5°, so perimeter 8(6 tan 22.5°) 48 tan 22.5° 19.88 ft. Pa A ¬1 2

19. side length 9 6 or 1.5 in., and 1 2 (1.5) 0.75 apothem 0.753 A ¬1 2 Pa ¬1 ) 2 (9)(0.753

¬3.3753 or about 5.8 in2 20. D; two sides are horizontal, lying on the lines y 1 and y 4. The lengths of the horizontal sides are |3 5| |1 7| 8. So the figure is a parallelogram, with height |4 (1)| or 5. A ¬bh ¬(8)(5) ¬40 units2

¬1 2 (19.88)(3)

¬29.8 ft2 12. side length 115 5 23 cm, and 1 2 (23) 11.5

central angle 360° 5 72°, and 1 2 (72°) 36° 1 1. 5 apothem tan 36° 15.828

A ¬1 2 Pa

¬1 2 (115)(15.828)

¬910.1 cm2

409

Chapter 11

11. By the Exterior Angle Theorem, mR mS ¬mSTP mR 90 ¬150 mR ¬60 12. Since pairs of vertical angles at C are congruent, and A and E are congruent, by AA similarity ABC EDC.

Chapter 11 Standardized Test Practice Pages 632–633 1. B;

2x 4

3 6 ¬18

2 31 3 x 3 ¬18

2.

3.

4.

5.

6.

7. 8. 9.

x 2 ¬18 x ¬16 x ¬16 B; the angle of the path from the school to the baseball field is a 90° angle, and the angle of Sam’s path from the library to the baseball field is greater than that. So the angle of Sam’s path is obtuse. A; let p, q, and r represent parts of the given statements. p: you exercise q: you maintain better health r: you will live longer Given: p → q and q → r. Use the Law of Syllogism to conclude p → r. That is, if you exercise, you will live longer. C; mADE ¬180 mDEA mEAD ¬180 40 60 ¬80 Since DE is a transversal for AD and BE, and corresponding angles ADE and BEC are congruent, A D and B E are parallel. D; because the front of the tent is isosceles and the entrance is an angle bisector, the two sides of the front of the tent are congruent triangles, by SAS. Then the two bases are of equal length, namely 3 ft, and so the distance between the stakes is 3 3 or 6 ft. D; the gazebo is a regular hexagon. The angle measuring x is an exterior angle of the hexagon. Each exterior angle of a regular hexagon 36 0 measures 6 or 60. So x 60. A; this is Theorem 10.5. 2 1 C; A 1 2 Pa 2 (6 9)(7.8) ¬210.6 cm The library coordinates are (4,3), and the fire station coordinates are (8, 3). The post office lies at the midpoint of the segment from (4, 3) to (8, 3). So the post office coordinates are given by x x 2

AB AC ED ¬ EC A B 1 2 ¬1 250 200 11 2 AB ¬250 200

¬140 13. The image of J(6,3) for the translation (x, y) → (x, y 5) is J (6, 3 5) or J (6, 2). 14. Use trigonometry. 1560

a. tan 38° ¬x 156 0 x ¬ tan 38° ¬1997 ft 1560 b. tan 35° ¬ y 1560 y ¬ tan 35°

¬2228 ft c. Use the results from (a) and (b). campground width ¬y x ¬2228 1997 ¬231 ft 15.

C

B

x

A D

a. Since B C is horizontal, D must lie on the x-axis. And since the slope of A B is 4 3 , the slope 4 of D C must be 3. So D must be located 4 units down and 3 units left of C(8,4), at D(5,0). b. AD 5, and height 4. A ¬bh ¬(5)(4) ¬20 units2

y y 2

4 8 3 3 1 2 1 2 M , ¬ 2 , 2

¬(2, 0) 10. Put the equation in slope-intercept form. 3x 6y ¬12 6y ¬3x 12 y ¬1 2x 2 The slope of the graph of the equation is m ¬1 2. The slope of the perpendicular line is the negative reciprocal of 1 2 , or 2.

Chapter 11

y

410

Chapter 12 Surface Area 2. In a square pyramid, the faces meet at a point. In a square prism the faces are perpendicular to each base. 3. Sample answer:

Page 635 Getting Started 1. True; points A, C, and D lie in plane N , so ADC lies in plane N . 2. False; points A, B, and C do not lie in plane K , so ABC does not lie in plane K. 3. Cannot be determined; neither the given information nor the figure allow a determination of whether or not the line containing A B is parallel to plane K. 4. False; the line containing A C lies in plane N and only lies in both plane N and plane K , so the line containing A C does not lie in plane K. 5. The figure is a trapezoid with bases b1 19 ft and b2 29 ft and height h 16 ft. The area is given by A 1 2 h(b1 b2).

4.

back view corner view

5. The base is a hexagon, and six faces meet at a point. So this solid is a hexagonal pyramid. The base is ABCDEF. The faces are ABCDEF, AGF, FGE, EGD, DGC, CGB, and BGA. The edges are A F , F E , E D , D C , C B , B A , A G , F G , G E , D G , C G , and B G . The vertices are A, B, C, D, E, F, and G. 6. The bases are squares. So this is a square prism. The bases are KJIH and MNOL. The faces are KJIH, MNOL, JNOI, JKMN, KHLM, and IHLO. The edges are K H , K J , J I, IH , J N , IO , H L , K M , N M , M L , N O , and L O . The vertices are H, K, J, I, L, M, N, and O. 7. The bases are circles. So this is a cylinder. The bases are circles P and Q. 8. To get round slices of cheese, slice the cheese parallel to the bases. To get rectangular slices, place the cheese on the slicer so the bases are perpendicular to the blade.

A 1 2 (16)(19 29) 384

The area of the figure is 384 ft2. 6. The figure is a trapezoid with bases b1 12 mm and b2 35 mm and height h 13 mm. The area is given by A 1 2 h(b1 b2). A 1 2 (13)(12 35) 305.5

The area of the figure is 305.5 mm2. 7. The figure is a triangle with base b 1.9 m and height h 1.9 m. The area is given by A 1 2 bh. A 1 2 (1.9)(1.9) 1.805

Rounded to the nearest tenth, the area of the figure is 1.8 m2. 8. A ¬r2

¬ d 2

2

2 ¬1 4 d


2 ¬1 4 (19.0)

¬283.5 cm2 9. A r2 (1.5)2 7.1 yd2 10. A ¬r2

back view corner view

2 ¬ d 2 2 ¬1 4 d 2 ¬1 4 (10.4)

10.

back view

¬84.9 m2 corner view

11.

12-1 Three-Dimensional Figures

back view


corner view

1. The Platonic solids are the five regular polyhedra. All of the faces are congruent, regular polygons. In other polyhedra, the bases are congruent parallel polygons, but the faces are not necessarily congruent.

12.

back view

corner view

411

Chapter 12

13.

top view

left view

front view right view

top view

left view


27. 28. 29. 30. 31.

14.

The resulting shape is a circle. The resulting shape is a rectangle. The resulting shape is a rectangle. The resulting shape is a square. intersecting three faces and parallel to base;

15. 32. intersecting three faces and edges of base; top view

left view


16. The bases are triangles. So this is a triangular prism. The bases are MNO, and PQR. The faces are MNO, PQR, OMPR, ONQR, and PQNM. The edges are M N , N O , O M , P Q , Q R , P R , Q N , M P , and O R . The vertices are M, N, O, P, Q, and R. 17. The base is a rectangle, and four faces meet in a point. So this solid is a rectangular pyramid. The base is DEFG. The faces are DEFG, DHG, GHF, FHE, and DHE. The edges are D G , F G , F E , E D , D H , E H , F H , and G H . The vertices are D, E, F, G, and H. 18. The base is a triangle, and three faces meet in a point. So this solid is a triangular pyramid. The base is IJK. The faces are IJK, ILK, KLJ, and ILJ. The edges are IK , K J , IJ , IL , K L , and L J . The vertices are I, J, K, and L. 19. The bases are circles. The solid is a cylinder. The bases are circles S and T. 20. The solid is a sphere. 21. The solid has a circle for a base and a vertex. So it is a cone. The base is circle B. The vertex is A. 22. 16: Yes; Euler’s formula is true. F V ¬E 2 5 6 ¬9 2 11 ¬11 17: Yes; Euler’s formula is true. F V ¬E 2 5 5 ¬8 2 10 ¬10 18: Yes; Euler’s formula is true. F V ¬E 2 4 4 ¬6 2 8 ¬8 19–21: No; these figures are not polyhedrons, so Euler’s formula does not apply. 23. No, not enough information is provided by the top and front views to determine the shape. 24. Sample answer: The speaker could be shaped like a rectangular prism, or the sides could be angled.

33. intersecting all four faces, not parallel to any face;

34. If the number of sides of a base of a pyramid increases infinitely, the solid that results is a cone. 35. If the number of sides of the bases of a prism increases infinitely, the solid that results is a cylinder. 36. The shapes seen in an uncut diamond are triangles and squares or rectangles. 37. The shapes seen in the emerald-cut diamond are rectangles, triangles, and quadrilaterals. 38. The shapes seen in the round-cut diamond are octagons, triangles, and quadrilaterals. 39a. 5 faces: triangular prism 39b. 6 faces: cube, rectangular prism, or hexahedron 39c. 6 faces: pentagonal pyramid 39d. 7 faces: hexagonal pyramid 39e. 8 faces: hexagonal prism 40. Yes, there is a pattern. The number of sides of the base of a prism is 2 less than the number of faces in the polyhedron. The number of sides of the base of a pyramid is 1 less than the number of faces. 41. No; the number of faces is not enough information to classify a polyhedron. A polyhedron with 6 faces could be a cube, rectangular prism, hexahedron, or a pentagonal pyramid. More information is needed to classify a polyhedron. 42. Polyhedra

Regular (Platonic Solids)

right view

25. The resulting shape is a parabola. 26. The resulting shape is a triangle. Chapter 12

Cubes

Tetrahedrons

Prisms

Pyramids

left view

412

43. Sample answer: Archaeologists use twodimensional drawings to learn more about the structure they are studying. Egyptologists can compare two-dimensional drawings of the pyramids and note similarities and any differences. Answers should include the following. • Viewpoint drawings and corner views are types of two-dimensional drawings that show three dimensions. • To show three dimensions in a drawing, you need to know the views from the front, top, and each side. 44. D; a circle cannot be formed by the intersection of a cube and a plane.

The figure is composed of two triangles, one rectangle, and one square. Find the area. 2 1 A ¬1 2 b1h1 2 b2h2 s w 2 1 ¬1 2 (3)(2) 2 (2)(5) 3 (5)(3)

¬32 The area is 32 units2. 55.

y

L (2, 2) M (0, 1) x

3

45. D; xx4 1x 1 1 1 1 4 3 2 1

P (4, 2)

The figure is composed of two triangles and a rectangle.

46. There are 6 planes of symmetry. Each plane contains the center of the tetrahedron and one edge, thus bisecting the opposite edge. 47. A cylinder has infinite planes of symmetry. Planes pass through the centers of the bases. 48. A sphere has infinite planes of symmetry. Planes pass through the center of the sphere.

1 A ¬1 2 b1h1 2 b2h2 w 1 ¬1 2 (2)(4) 2 (2)(1) (3)(2)

¬11 The area is 11 units2. 56. Base and Sides: Each pair of opposite sides of a parallelogram has the same measure. Each base is 15 m and each side is 12 m. Perimeter: The perimeter of a polygon is the sum of the measures of its sides. So, the perimeter of the parallelogram is 2(12) 2(15) or 54 m. Height: Use a 30-60-90 triangle to find the height. Recall that if the measure of the leg opposite the 30 angle is x, then the length of the hypotenuse is 2x, and the length of the leg opposite the 60 angle is x 3. 12 2x 16 x So, the height of the parallelogram is 6 3 meters. Area: A ¬bh ¬(15)(6 3) ¬90 3 ¬155.9 The perimeter is 54 m and the area is approximately 155.9 m2. 57. Base and Sides: Each pair of opposite sides of a parallelogram has the same measure. Each base is 25 ft and each side is 20 ft. Perimeter: The perimeter of a polygon is the sum of the measures of its sides. So, the perimeter of the parallelogram is 2(25) 2(20) or 90 ft. Height: Use a 30-60-90 triangle to find the height. Recall that if the measure of the leg opposite the 30 angle is x, then the length of the hypotenuse is 2x, and the length of the leg opposite the 60 angle is x 3. 20 2x 10 x So, the height of the parallelogram is 10 3 feet.


87 49. P(steak) 36 0 0.242 87 102 118 50. P(not seafood) 0.853 360 102 118

0.611 51. P(either pasta or chicken) 360 53 118

52. P(neither pasta nor steak) 0.475 360

53.

y

A (1, 4)

D (3, 1)

B (4, 1) x

C (1, 2) The figure is composed of two triangles, each with height 3 and base 7. Find the area.

A ¬2 1 2 bh

¬bh ¬(7)(3) ¬21 The area is 21 units2. 54.

y

H (1, 1) G (2, 1)

F (2, 4)

N (0, 2)

J (4, 1) x

K (6, 4)

413

Chapter 12

Area: A ¬bh ¬(25)(103 ) ¬250 3 ¬433.0 The perimeter is 90 ft and the area is approximately 433.0 ft2. 58. Base and Sides: Each pair of opposite sides of a parallelogram has the same measure. Each base is 68 in. and each side is 42 in. Perimeter: The perimeter of a polygon is the sum of the measures of its sides. So, the perimeter of the parallelogram is 2(68) 2(42) or 220 in. Height: Use a 45-45-90 triangle to find the height. Recall that if the measure of each leg is x, then the length of the hypotenuse is x 2. 42 ¬x 2

3.

4.

5.

4 7

6

7

42 ¬x 2

212 ¬x So, the height of the parallelogram is 21 2 inches. Area: A ¬bh ¬(68)(212 ) ¬1428 2 ¬2019.5 The perimeter is 220 in. and the area is approximately 2019.5 in2. 59. A w 60. A ¬w (20)(15) ¬(4)(13) 300 ¬52 The area is 300 cm2. The area is 52 ft2. 61. A w (60)(72) 4320 The area is 4320 in2. 62. A s2 1.72 2.9 The area is approximately 2.9 m2.

Surface area 2(4 7) 2(4 6) 2(6 7) 56 48 84 188 The surface area of the rectangular prism is 188 in2. 6. Use the Pythagorean Theorem to find the height of the prism. 172 ¬82 h2 289 ¬64 h2 225 ¬h2 15 ¬h

9 15

8

17

12-2 Nets and Surface Area Page 645 Check for Understanding 1. Sample answer: Surface area 1 8 9 9 15 9 17 1 2 8 15 2 8 15 72 135 153 60 60 480 The surface area of the right triangular prism is 480 ft2.

2. On isometric dot paper, the dots are arranged in triangles, which aid in drawing three-dimensional objects. On rectangular dot paper, the dots are arranged in squares, which aid in drawing the nets and orthogonal views of three-dimensional objects.

Chapter 12

414

13.

7.

14.

15.

Surface area ¬42 4 1 2 46 ¬16 48 ¬64 The surface area of the square pyramid is 64 cm2. 8. C; the net only forms three of the four sides. Two of the triangles overlap rather than being two different faces.

Surface area 2(32) 4(3 4) 18 48 66 The surface area of the rectangular prism is 66 units2. 16.


10.

Surface area 2(2 5) 2(2 6) 2(5 6) 20 24 60 104 The surface area of the rectangular prism is 104 units2. 17.

11.

12.

Surface area ¬42 4 1 2 45 ¬16 40 ¬56 The surface area of the square pyramid is 56 units2.

415

Chapter 12

18.

Surface area 1

2 2 6 8 5 8 5 6 5 10 48 40 30 50 168 The surface area of the triangular prism is 168 units2. 21. Use the Pythagorean Theorem to find the height of the triangle. 2

52 ¬2 h2 4

Surface area ¬22 4 1 2 24 ¬4 16 ¬20 The surface area of the square pyramid is 20 units2.

25 ¬4 h2 21 ¬h2 21 ¬h

19.

1

Surface area ¬2(5 7) 4 7 2 2 4 21 ¬70 28 4 21 ¬116.3 The surface area of the triangular prism is approximately 116.3 units2. 22. Use the Pythagorean Theorem to find the unknown edge length. c2 ¬a2 b2 c2 ¬(8 6)2 62 c2 ¬4 36 c2 ¬40 c ¬ 40 c ¬2 10 Find the area of the trapezoid.

Surface area 6(4.52) 121.5 The surface area of the cube is 121.5 units2. 20. Use the Pythagorean Theorem to find the hypotenuse of the right triangle. c2 ¬a2 b2 c2 ¬62 82 c2 ¬36 64 c2 ¬100 c ¬10

1

A ¬2h(b1 b2) 1

¬2(6)(6 8) ¬42

Chapter 12

416

Surface area 2 13.5 5 6 2(3 5) 5 32 27 30 30 152 108.2 The surface area of the prism is approximately 108.2 units2. 24. 6.99 ft

6.99 ft

2.46 ft 9.89 ft

2.46 ft

2.46 ft

6.99 ft 6.99 ft

Use the Pythagorean Theorem to find the hypotenuse. c2 ¬a2 b2 c2 ¬6.992 6.992 c ¬ 97.72 02 The thickness of the sandwich is 29.5

8 13.5 8 29.5 in. 12 ft. Surface area ¬2 2 6.992 26.99 12 29.5 02 12 97.72 1

Surface area 2(6 8) 82 210 8 2 42 96 64 1610 84 294.6 The surface area of the prism is approximately 294.6 units2.

29.5

¬107.5 The surface area of the sandwich is approximately 107.5 ft2. 25.

23. Use the Pythagorean Theorem to find the unknown edge length. c2 ¬a2 b2 c2 ¬(6 3)2 32 c2 ¬9 9 c2 ¬18 c ¬ 18 c ¬3 2 Find the area of the trapezoid.

26.

1

A ¬2h(b1 b2) 1

¬2(3)(3 6)

27.

28.

¬13.5

E

F

H B A

29.

30.

N

C D

A

B

R

S

R

Q U

T

P N

417

H

Q

T

N

E

D

R

M

F G

Q

Chapter 12

31. W

X

U

R

T T

W X

Figure C:

Z

R

V

Y Z Z

Surface area 2(2 4) 2(2 5) 2(4 5) 16 20 40 76 The surface area of the rectangular prism is 76 units2. 36. Figure A: Surface area 6(2 2) 24 The surface area of the cube is 24 units2. Figure B: Use the Pythagorean Theorem to find the height of the triangles.

32.

33.

2

22 ¬h2 2 2

34.

35. Figure A: 37. Surface area 6(1 1) 6 The surface area of the cube is 6 units2. Figure B: Use the Pythagorean Theorem to find the height of the triangles.

38.

2

12 ¬h2 2 1

1

1 ¬h2 4

39. 40.

3 4 ¬h2 3 2 ¬h

3 Surface area ¬3(1 3) 2 2 1 2 3 ¬9 2 1

The surface area of the triangular prism is

9 23 units2. 41.

Chapter 12

418

4 ¬h2 1 3 ¬h2 3 ¬h 1 Surface area ¬3(2 6) 2 2 2 3 ¬36 2 3 The surface area of the triangular prism is (36 2 3) units2. Figure C: Surface area 2(4 8) 2(4 10) 2(8 10) 64 80 160 304 The surface area of the rectangular prism is 304 units2. The surface area quadruples when the dimensions are doubled. For example, the surface area of the cube is 6(12) or 6 square units. When the dimensions are doubled the surface area is 6(22) or 24 square units. When dimensions are tripled, the surface area will be nine times greater than the original surface area. For example, the surface area of the cube is 6(12) or 6 square units. The new surface area is 6(32) or 54 square units. No; 5 and 3 are opposite faces; the sum is 8. Sample answer: Car manufacturers want their cars to be as fuel efficient as possible. If the car is designed so the front grill and windshield have a smaller surface area, the car meets less resistance from the wind. Answers should include the following. • A small compact car has less surface facing the wind than a larger truck, so smaller sedans tend to be more efficient than larger vehicles. • Of the two-dimensional models studied in this chapter, orthogonal drawings would be helpful to the designers. C; only net C can be folded into a rectangular prism.

42. B; 16a3 54b3 2(8a3 27b3) 2[(2a)3 (3b)3] 2(2a 3b)(4a2 6ab 9b2)

2. Sample answer: The bases are ACHG and BDFE. The lateral faces are ABDC, GEFH, BEGA, and DFHC. The lateral edges are B A , E G , F H , and C D . base

D

F

Page 648 Maintain Your Skills B

43. The resulting shape is a rectangle. 44. The resulting shape is a triangle. 45. The resulting shape is a rectangle.

base

A

(20)(20)

46. P(butterfly in the flower bed) ¬ (100)(200) ¬0.02 47. mFLJ 180 because it is a semicircle. By the Inscribed Angle Theorem,

C

H G

3. Use the Pythagorean Theorem to find the measure of the hypotenuse of the triangular base. c2 ¬a2 b2 c2 ¬82 152 c2 ¬64 225 c2 ¬289 c ¬17 L Ph (17 15 8)(21) (40)(21) 840 T ¬L 2B

mFHJ ¬1 2 mFLJ ¬1 2 (180)

¬90 48. mLK 60 because it is 1 6 the measure of a circle (360). 49. mGHL 240 because it is 4 6 the measure of a circle (360). By the Inscribed Angle Theorem,

¬840 2 1 2 bh

mLFG ¬1 2 mGHL

¬840 (8)(15) ¬840 120 ¬960 The lateral and surface areas are 840 units2 and 960 units2, respectively. 4. L(7 9 base) Ph (2 7 2 9)(6) 192 L(6 9 base) Ph (2 6 2 9)(7) 210 L(6 7 base) Ph (2 6 2 7)(9) 234 T L 2B 234 2(6 7) 234 84 318 The lateral areas are 192 units2 (7 9 base), 210 units2 (6 9 base), and 234 units2 (6 7 base). The surface area is 318 units2. 5. The perimeter of the ceiling (base) is 2(20) 2(15) 40 30 70 ft. Find the total surface area to be painted. TLB Ph B (70)(12) (20)(15) 840 300 1140 The surface area to be painted is 1140 ft2.

¬1 2 (240)

¬120 50. A bh 16 14 224 The area of the parallelogram is 224 ft2. 51. A ¬1 2 h(b1 b2) ¬1 2 7(6 12)

¬63 The area of the trapezoid is 63 cm2. 52. A ¬1 2 bh ¬1 2 6.5 4

¬13 The area of the triangle is 13 yd2. 53. A ¬1 2 h(b1 b2) ¬1 2 10(13 9)

¬110 The area of the trapezoid is 110 cm2.

12-3 Surface Areas of Prisms Page 651

lateral edges lateral faces

E


1. In a right prism the altitude is also a lateral edge. In an oblique prism, the lateral edges are not perpendicular to the base.

Pages 651–654 Practice and Apply 6. L(3 4 base) Ph (2 3 2 4)(12) 168

419

Chapter 12

7.

8.

9.

10.

11.

12.

13.

L(3 12 base) Ph (2 3 2 12)(4) 120 L(4 12 base) Ph (2 4 2 12)(3) 96 The lateral areas are 168 units2 (3 4 base), 120 units2 (3 12 base), and 96 units2 (4 12 base). L Ph (4 5 7)(8) 128 The lateral area is 128 units2. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 c2 ¬72 82 c2 ¬49 64 c2 ¬113 c ¬113 L Ph (7 8 113 )(10) 256.3 The lateral area is approximately 256.3 units2. L Ph (2 4 3 4 5)(9) 162 The lateral area is 162 units2. L Ph (2 7 2 4 8 2)(9) 342 The lateral area is 342 cm2. Find the lateral area of the hollowed-out prism, including the inner faces. L (outer perimeter)h (inner perimeter)h (4 4)(8) (4 1)(8) 160 The lateral area is 160 units2 (square base). L 2(42 12) 2(4 8) 4(1 8) 2(15) 2(32) 4(8) 30 64 32 126 The lateral area is 126 units2 (rectangular base). The surface area of a cube is given by A 6s2, where s is the length of a lateral edge. 864 6s2 144 s2 812 s The length of the lateral edge is 12 in. Use the Pythagorean Theorem to find the measure of the hypotenuse of the triangular base. c2 ¬a2 b2 c2 ¬52 122 c2 ¬169 c ¬13 So, P 5 12 13 30. T ¬L 2B T ¬Ph 2B 540 ¬30(h) 2 1 2 5 12

L ¬Ph 156 ¬P(13) 512 ¬P The perimeter of the base must be 12 inches. There are three rectangles with integer values for the dimensions that have a perimeter of 12. The dimensions of the base could be 5 1, 4 2, or 3 3. 15. L ¬Ph 96 ¬P(4) 24 ¬P The perimeter of the base must be 24 meters. There are six rectangles with integer values for the dimensions that have a perimeter of 24. The dimensions of the base could be 1 11, 2 10, 3 9, 4 8, 5 7, or 6 6. 16. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 172 ¬a2 82 289 ¬a2 64 225 ¬a2 15 ¬a T ¬L 2B ¬Ph 2B 14.

¬(8 15 17)(4) 2 1 2 8 15

¬280 The surface area of the prism is 280 units2. 17. T L 2B Ph 2B (3 3 3 3)(8) 2(3 3) 114 The surface area of the prism is 114 units2. 18. T L 2B Ph 2B (2 4 2 11)(7.5) 2(4 11) 313 The surface area of the prism is 313 units2. 19. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 152 ¬a2 92 225 ¬a2 81 144 ¬a2 12 ¬a T ¬L 2B ¬Ph 2B ¬(9 12 15)(11.5) 2 1 2 9 12 ¬522 The surface area of the prism is 522 units2.

540 ¬30h 60 480 ¬30h 16 ¬h The height is 16 cm. Chapter 12

420

23. L Ph (15 15 15 15)(10) 600 60 0 400 1.5 gallons needed for 1 coat

20. Use trigonometry, the Pythagorean Theorem, and the figure to find the measures of the missing sides of the bases. 60

c

4

9

So, 3 gallons are needed for 2 coats. 24. T L B Ph B (15 15 15 15)(10) 152 825 For two coats, the surface area is 1650 ft2.

h

16 50 400 4.125

Since only whole gallons may be purchased, 5 gallons must be purchased to paint the walls and ceiling. 5 $16 $80, so it will cost $80 to paint the walls and ceiling. 25. Estimate the surface area of the Corn Palace using a rectangular prism. L Ph (2 310 2 185)(45) 44,550 The area to be covered is estimated to be 44,550 ft2. 26. L ¬Ph ¬(2 310 2 185)(45) ¬44,550

tan60 ¬h 4 4tan60 ¬h 4 3 ¬h c2 ¬a2 b2 c2 ¬42 (43 )2 c2 ¬16 48 c2 ¬64 c ¬8 Find the surface area. T ¬Ph 2B ¬(5 8 9 43 )(11) 2 1 )(5 9) 2 (43

¬415.2 The surface area is approximately 415.2 units2. 21. Use trigonometry, the Pythagorean Theorem, and the figure to find the measures of the missing sides of the bases.

44,5 50 15 ¬2970

It takes 2970 bushels of grain to cover the Corn Palace. 27. The actual amount needed will be higher because the building is not a perfect rectangular prism. 28. Use the Pythagorean Theorem to find the missing measure. c2 ¬a2 b2 c2 ¬22 (7 6)2 c2 ¬4 1 c ¬ 5 Find the area of the trapezoids.

7

c

h

h

60 4

A ¬1 2 h(b1 b2)

11

¬1 2 (2)(6 7)

tan 60 ¬h 4 4tan60 ¬h 4 3 ¬h c2 ¬a2 b2 c2 ¬42 (43 )2 2 c ¬16 48 c2 ¬64 c ¬8 Find the surface area. T ¬Ph 2B ¬(7 8 11 43 )(10) 2 1 )(7 11) 2 (43

¬13 Surface area 2(13) 62 6 5 26 36 65 75.4 The surface area of the glass is approximately 75.4 ft2. 29. Use the Pythagorean Theorem to find the measures of the third sides of the triangular bases. Prism A: c2 ¬a2 b2 c2 ¬32 42 c2 ¬9 16 c2 ¬25 c ¬5

¬454.0 The surface area is approximately 454.0 units2. 22. L Ph (15 15 15 15)(10) 600 No, the walls are 600 ft2; 1.5 gallons will only be enough for 1 coat.

421

Chapter 12

Prism B: c2 ¬a2 b2 c2 ¬62 82 c2 ¬36 64 c2 ¬100 c ¬10 Prism C: c2 ¬a2 b2 52 ¬a2 32 25 ¬a2 9 16 ¬a2 4 ¬a The base of Prism A the base of Prism C because of the SSS Postulate. The sides of the bases of Prism B are proportional to the sides of the bases of Prisms A and C so base of A base of B and base of C base of B. 30. Using the side lengths calculated in Exercise 29, the perimeters of the bases are as follows. Prism A: P 3 4 5 12 Prism B: P 6 8 10 24 Prism C: P 3 4 5 12 So, the ratios of the perimeters of the bases are A : B 1 : 2, B : C 2 : 1, and A : C 1 : 1. 31. Prism A: B ¬1 2 bh

33. 34.

¬1 2 (3)(4) ¬6 Prism B: B ¬1 2 bh

35.

¬1 2 (6)(8) ¬24 Prism C: Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 52 ¬a2 32 25 ¬a2 9 16 ¬a2 4 ¬a

36.

B ¬1 2 bh ¬1 2 (3)(4)

¬6 So, the ratios of the areas of the bases of the prisms are A : B 1 : 4, B : C 4 : 1, and A : C 1 : 1. 32. Using the values of the perimeters calculated in Exercise 30, the surface areas are as follows. Prism A: T ¬Ph 2B

37.

¬(12)(6.5) 2 1 2 34

¬90 Prism B: T ¬Ph 2B ¬(24)(13) 2 1 2 68 ¬360 Prism C: T ¬Ph 2B

¬8h 2 ¬4h

¬(12)(10) 2 1 2 34 ¬132

Chapter 12

So, the ratios of the surface areas of the prisms are A : B 1 : 4, B : C 30 : 11, and A : C 15 : 22. A and B, because the heights of A and B are in the same ratio as perimeters of bases. Surface area of TV Ph 2B (2 20 2 30)(84) 2(20 30) 8400 1200 9600 cm2 Surface area of VCR Ph 2B (100)(76) 2(600) 7600 1200 8800 cm2 Surface area of CD Ph 2B (100)(60) 2(600) 6000 1200 7200 cm2 Surface area of video game system Ph 2B (100)(39) 2(600) 3900 1200 5100 cm2 Surface area of DVD Ph 2B (100)(35) 2(600) 3500 1200 4700 cm2 No, the surface area of the finished product will be the sum of the lateral areas of each prism plus the area of the bases of the TV and DVD prisms. It will also include the area of the overhang between each prism, but not the area of the overlapping prisms. Area of ends 10(20 30) 6000 Area of top (30)(84) 2520 Area of bottom (30)(35) 1050 Area of sides 2(20)(84 76 60 39 35) 11,760 Area of overhangs 30[(84 76) (76 60) (60 39) (39 35)] 1470 Total surface area 6000 2520 1050 11,760 1470 22,800 The total surface area of the finished model is 22,800 cm2. L ¬Ph 144 ¬3w h ¬2w Find the perimeter in terms of h. P ¬2 2w ¬2(3w) 2w ¬8w

422

Find h. 144 ¬Ph 144 ¬(4h)h 144 ¬4h2 36 ¬h2 6 ¬h So, P (4)(6) 24, w 6 2 3, and (3)(3) 9. T Ph 2B (24)(6) 2(3)(9) 144 54 198 The surface area is 198 cm2. 38. Sample answer: Brick masons use the measurements of the structure and the measurements of the bricks to find the number of bricks that will be needed. Answers should include the following. • The lateral area is important because the sides of the brick will show. Also, depending on the project, only the lateral area of the structure may be covered with brick. • It is important to overestimate the number of bricks ordered in case some are damaged or the calculations were inaccurate. 39. B; 121.5 6s2 where s is the length of each edge.

8 10

8 6

12

12 6 10

8 8

T Ph 2B T (6 8 10)(12) 2 1 2 68 T 288 48 T 336 The surface area of the triangular prism is 336 units2.

45.

121.5 s2 ¬ 6 121.5 s ¬ 6

s ¬4.5 m

4 a 16 (a 4)(a 4) a 40. D; 4a 16 4(a 4) 4 ,a 4 41. L Ph L (2 16 2 20)(18) L 1296 cm2 T L 2B T 1296 2(20)(15) T 1896 cm2 2

T Ph 2B T (2 3 2 4)(6) 2(3)(4) T 84 24 T 108 The surface area of the rectangular prism is 108 units2.

42. L Ph L (1 4 4.6)(3) L 28.8 cm2 T L 2B 46.

T 28.8 2 1 2 0.8 4.6 2 T 32.48 cm 43. See students’ work.

Page 654 Maintain Your Skills 44. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 c2 ¬62 82 c2 ¬36 64 c2 ¬100 c ¬10

T Ph 2B T (2 4 2 5)(3) 2(4)(5) T 54 40 T 94 The surface area of the rectangular prism is 94 units2. 47.

back view

423

Chapter 12

53. To find this ratio, convert the height of the house to inches from feet, then divide the height of the drawing by the height of the house. height of drawing in inches 5.5 5.5 1 height of house in inches 33 12 396 72 1 The scale factor of the drawing is 72 .

corner view

54. Use a calculator. A r2 (40)2 5026.55 cm2 55. Use a calculator. A ¬r2

48.

back view

2

¬d 2

2

5 0 ¬ 2

¬(25)2 ¬1963.50 in2 56. Use a calculator. A r2 (3.5)2 38.48 ft2

corner view

49. Since the radius of Q is 24, AQ QC 24. QB BC ¬QC QB ¬QC BC QB ¬24 5 QB ¬19 AB AQ QB AB 24 19 AB 43 50. Since the radius of Q is 24, AC 48. Since the radius of R is 16, RD BR 16. AD AC CR RD AD 48 CR 16 AD 64 CR Find CR. BC CR ¬BR CR ¬BR BC CR ¬16 5 CR ¬11 So, AD 64 11 75. 51. Since the radius of Q is 24, QC 24. Since the radius of R is 16, BR 16. QB BC ¬QC QB ¬QC BC QB ¬24 5 QB ¬19 BC CR ¬BR CR ¬BR BC CR ¬16 5 CR ¬11 QR QB BC CR QR 19 5 11 QR 35 52. Let x be the distance climbed by the airplane as it flies (horizontally) 50 miles. A right triangle is formed by x (leg opposite), the 50-mile horizontal distance (leg adjacent), and the path of the airplane (hypotenuse). Find x.

12-4 Surface Areas of Cylinders Page 657


1. Multiply the circumference of the base by the height and add the area of each base. 2. Sample answer:

3. Jamie; since the cylinder has one base, the surface area will be the sum of the lateral area and one base. 4. Use a calculator. T 2rh 2r2 2(4)(6) 2(4)2 251.3 The surface area is approximately 251.3 ft2. 5. Use a calculator. T ¬2rh 2r2 2

d ¬2d 2h 22 2 ¬dh 1 2 d

2 ¬(22)(11) 1 2 (22)

¬1520.5 The surface area is approximately 1520.5 m2.

leg opposite

tan3.5 ¬ leg adja cent x tan3.5 ¬ 50

50tan3.5 ¬x Use a calculator to find x. Keystrokes: 50 TAN 3.5 ENTER x 3.1 mi The total height above sea level is approximately 3 3.1 6.1 mi. Chapter 12

57. Use a calculator. A ¬r2 ¬(82)2 ¬21,124.07 mm2

424

6. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 96 ¬2r(8) 2r2 96 ¬16r 2r2 48 ¬8r r2 0 ¬r2 8r 48 0 ¬(r 12)(r 4) r ¬4 or 12 Since the radius of a circle cannot have a negative value, 12 is eliminated. So, the radius of the base is 4 cm. 7. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 140 ¬2r(9) 2r2 140 ¬18r 2r2 70 ¬9r r2 0 ¬r2 9r 70 0 ¬(r 14)(r 5) r ¬5 or 14 Since the radius of a circle cannot have a negative value, 14 is eliminated. So, the radius of the base is 5 ft. 8. Find the area of one label. L ¬2rh

12. Use a calculator. T 2rh 2r2 2(14)(14) 2(14)2 2463.0 The surface area is approximately 2463.0 mm2. 13. Use a calculator. T 2rh 2r2 2(4)(6) 2(4)2 251.3 The surface area is approximately 251.3 ft2. 14. Use a calculator. T ¬2rh 2r2 2

d ¬2d 2 h 2 2 2 ¬dh 1 2 d

2 ¬(8.2)(7.2) 1 2 (8.2)

¬291.1 The surface area is approximately 291.1 yd2. 15. Use a calculator. T 2rh 2r2 2(0.9)(4.4) 2(0.9)2 30.0 The surface area is approximately 30.0 cm2. 16. Use a calculator. T ¬2rh 2r2

¬2d 2 h

2

d ¬2d 2h 22

¬dh ¬(2.5)(4) ¬10 Find the area of 3258 labels. Use a calculator. 3258L 3258(10) 102,353.1 The total area is approximately 102,353.1 in2.

2 ¬dh 1 2 d 2 ¬(9.6)(3.4) 1 2 (9.6)

¬247.3 The surface area is approximately 247.3 m2. 17. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 48 ¬2r(5) 2r2 48 ¬10r 2r2 24 ¬5r r2 0 ¬r2 5r 24 0 ¬(r 8)(r 3) r ¬3 or 8 Since the radius of a circle cannot have a negative value, 8 is eliminated. So, the radius of the base is 3 cm. 18. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 340 ¬2r(7) 2r2 340 ¬14r 2r2 170 ¬7r r2 0 ¬r2 7r 170 0 ¬(r 17)(r 10) r ¬10 or 17 Since the radius of a circle cannot have a negative value, 17 is eliminated. So, the radius of the base is 10 in.

Pages 657–658 Practice and Apply 9. Use a calculator. T 2rh 2r2 2(13)(15.8) 2(13)2 2352.4 The surface area is approximately 2352.4 m2. 10. Use a calculator. T ¬2rh 2r2 2

d ¬2d 2h 22 2 ¬dh 1 2 d

2 ¬(13.6)(1.9) 1 2 (13.6)

¬371.7 The surface area is approximately 371.7 ft2. 11. Use a calculator. T ¬2rh 2r2 2

d ¬2d 2h 22 2 ¬dh 1 2 d

2 ¬(14.2)(4.5) 1 2 (14.2)

¬517.5 The surface area is approximately 517.5 in2.

425

Chapter 12

24. L ¬2rh

19. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 320 ¬2r(12) 2r2 320 ¬24r 2r2 160 ¬12r r2 0 ¬r2 12r 160 0 ¬(r 20)(r 8) r ¬8 or 20 Since the radius of a circle cannot have a negative value, 20 is eliminated. So, the radius of the base is 8 m. 20. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 425.1 ¬2r(6.8) 2r2 425.1 ¬13.6r 2r2 0 ¬2r2 13.6r 425.1 Use the quadratic formula to find r. a ¬2 b ¬13.6 c ¬425.1

¬2d 2h ¬dh ¬(5)(13) ¬204.2 The lateral area of the silo is approximately 204.2 m2. 25. From Exercise 24, L 65. Use the formula for lateral area to write and solve an equation for the radius. L ¬2rh 65 ¬2r(26) 1.25 ¬r The radius of the silo is 1.25 m. x 26.

x– 2

Let the diameter of the circle be x. A regular hexagon can be separated into 6 congruent nonoverlapping equilateral triangles. The sides of each triangle are 2x. The perimeter of the hexagon is 3x. The lateral area of the hexagonal pencil is 33x. The radius of the circle is also 2x. The circumference of the circle is 22x or x. The lateral area is approximately 34.6x square inches. The cylindrical pencil has the greater surface area. 27. Sample answer: Extreme sports participants use a semicylinder for a ramp. Answers should include the following. • To find the lateral area of a semicylinder like the half-pipe, multiply the height by the circumference of the base and then divide by 2. • A half-pipe ramp is half of a cylinder if the ramp is an equal distance from the axis of the cylinder. 28. B; T ¬2rh 2r2

b ac b 4 r ¬ 2a 2 4(2)( 13.6 (13.6 ) 425.1 ) ¬ 2

2(2)

¬5.5 or 12.3 Since the radius of a circle cannot have a negative value, 12.3 is eliminated. So, the radius of the base is approximately 5.5 ft. 21. Since L 2rh, the lateral areas will be in the ratio 3 : 2 : 1. L1 ¬25 2 (9)

¬141.4 L2 ¬25 2 (6) ¬94.2 L3 ¬25 2 (3) ¬47.1 The lateral areas are approximately 141.4 in2, 94.2 in2, and 47.1 in2. 22. To find the amount of aluminum foil needed to cover the inside of the reflector, divide the formula for surface area of a cylinder by 2.

2

d ¬2d 2h 22 2 ¬dh 1 2 d

2r 2rh T ¬ 2 2

¬rh r2

2 ¬(8.2)(13.4) 1 2 (8.2)

¬450.8 cm2 29. C; let x be the number of adult tickets sold. Then 200 x is the number of student tickets sold. total sales ¬adult sales student sales 500 ¬5x 2(200 x) 500 ¬5x 400 2x 100 ¬3x 33.3 ¬x Since the total sales were more than $500, the minimum number of adult tickets sold was 34. 30. The locus of points 5 units from a given line is a cylinder with a radius of 5 units.

2

d ¬d 2h 2

1 2 ¬1 2 dh 4 d

2

1 1 1 ¬1 2 5 2 (18) 4 5 2 ¬179.3 Approximately 179.3 in2 of aluminum foil is needed. 23. T L 2B 2rh 2r2 Triple the height. T 2r(3h) 2r2 3(2rh) 2r2 3L 2B The lateral area is tripled. The surface area is increased, but not tripled.

Chapter 12

5

426

31. The locus of points equidistant from two opposite vertices of a face of a cube is a plane perpendicular to the line containing the opposite vertices of the face of the cube.

39. Use the Pythagorean Theorem to find x. c2 ¬a2 b2 (5 x)2 ¬52 122 25 10x x2 ¬25 144 x2 10x 144 ¬0 (x 18)(x 8) ¬0 8 or 18 ¬x Since the length of a segment cannot be negative, 18 is eliminated. So, x 8. 40. Use the Law of Cosines since the measures of two sides and the included angle are known. a2 ¬b2 c2 2bccosA a2 ¬6.32 7.12 2(6.3)(7.1)cos54 a2 ¬90.1 89.46cos54 a ¬ 90.1 89.46 cos54 a ¬6.1 Use the Law of Sines to find mB and mC.

1 unit

Page 659 Maintain Your Skills 32. L(8 15 base) Ph (2 8 2 15)(6) 276 L(6 15 base) (2 6 2 15)(8) 336 L(8 6 base) (2 8 2 6)(15) 420 The lateral areas are 276 units2 (8 15 base), 336 units2 (6 15 base), and 420 units2 (8 6 base). 33. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 c2 ¬52 122 c2 ¬25 144 c2 ¬169 c ¬13 L Ph (5 12 13)(10) 300 The lateral area is 300 units2. 34. L(8 18 base) Ph (2 8 2 18)(6) 312 L(6 18 base) (2 6 2 18)(8) 384 L(8 6 base) (2 8 2 6)(18) 504 The lateral areas are 312 units2 (8 18 base), 384 units2 (6 18 base), and 504 units2 (8 6 base). 35. 36.

sinB sinA b ¬ a b sinB ¬asinA b sinA B ¬sin1a 6.3 B ¬sin1 6.1 25 sin54

B ¬56.3 C sin sinA c ¬a

C ¬sin1acsinA 7.1 C ¬sin1 6.125 sin54

C ¬69.7 So, mB 56.3, mC 69.7, and a 6.1. 41. Use the Angle Sum Theorem to find mA. mA mB mC ¬180 mA 47 69 ¬180 mA ¬64 Use the Law of Sines to find b and c. sinA sinB a ¬b nB asi b ¬ sinA

15sin 47 b ¬ sin64

b ¬12.2

sinA sinC a ¬c nC asi c ¬ sinA 15sin 69 c ¬ sin64

c ¬15.6 So, mA 64, b 12.2, and c 15.6. 42. A ¬1 2 bh

37. According to Theorem 10.11 on page 554, two segments that originate from the same exterior point and are tangent to a circle are congruent. So, x 27. 38. Use the Pythagorean Theorem to find x. c2 ¬a2 b2 (4 6)2 ¬x2 62 100 ¬x2 36 64 ¬x2 8 ¬x

¬1 2 (20)(17)

¬170 The area of the triangle is 170 in2. 43. A ¬1 2 h(b1 b2) ¬1 2 (6)(7 11)

¬54 The area of the trapezoid is 54 cm2. 44. A ¬1 2 bh ¬1 2 (38)(13)

¬247 The area of the triangle is 247 mm2.

427

Chapter 12

2. A regular pyramid is only a regular polyhedron if all of the faces including the base are congruent regular polygons. Since the faces of a pyramid are triangles, the only regular pyramid that is also a regular polyhedron is a tetrahedron. 3. The slant height is the hypotenuse of a right triangle with legs that are the altitude and a segment with a length that is one-half the side measure of the base. Use the Pythagorean Theorem to find the slant height of the regular pyramid. c2 ¬a2 b2 2 ¬22 72 ¬53 Find the surface area. T ¬1 2 P B


2.

corner view

3. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 82 ¬a2 62 64 ¬a2 36 28 ¬a2 28 ¬a 27 ¬a L Ph (6 8 27 )(12) 231.5 The lateral area of the prism is approximately 231.5 m2. 4. From Question 3, L (6 8 2 7)(12) T ¬L 2B ¬Ph 2B

¬1 42 2 (4 4 4 4)53

¬74.2 The surface area of the regular pyramid is approximately 74.2 ft2. 4. The altitude, slant height, and apothem form a right triangle. Use the Pythagorean Theorem to find the length of the apothem. Let x represent the length of the apothem. c2 ¬a2 b2 (32 )2 ¬x2 32 18 ¬x2 9 9 ¬x2 3 ¬x The side measure of the base is 2x 2(3) 6. Find the surface area.

¬(6 8 27 )(12) 2 1 2 6 27

¬263.2 The surface area of the prism is approximately 263.2 m2. 5. Use the formula for surface area to write and solve an equation for the radius. T ¬2rh 2r2 560 ¬2r(11) 2r2 280 2 ¬11r r

T ¬1 2 P B

280 0 ¬r2 11r

¬1 ) 62 2 (6 6 6 6)(32

Use the quadratic formula to find r. a ¬1 b ¬11 280 c ¬

¬86.9 The surface area of the regular pyramid is approximately 86.9 cm2. 5. The slant height is the hypotenuse of a right triangle with legs that are a lateral edge and a segment with a length that is one-half the side measure of the base. Use the Pythagorean Theorem to find the measure of the slant height. c2 ¬a2 b2

b ac b 4 r ¬ 2a 2

11

280 4(1) 11 2

¬ 2(1) ¬5.4 or 16.4 Since the radius of a circle cannot have a negative value, 16.4 is eliminated. So, the radius of the base is approximately 5.4 ft.

2

10 132 ¬2 2

169 ¬2 25 144 ¬2 12 ¬ Find the surface area.

12-5 Surface Areas of Pyramids

T ¬1 2 P B 2 ¬1 2 (10 10 10 10)(12) 10


¬340 The surface area of the regular pyramid is 340 cm2. 6. To find the amount of paper used for one pyramid, find the lateral area of the pyramid.

1. Sample answer:

L ¬1 2 P square base (regular)

Chapter 12

¬1 2 (2 2 2 2)(4)

rectangular base (not regular)

¬16

428

Find the total amount of paper used given that there are 6 pyramids per star. 6L 6(16) 96 The amount of paper used is 16 in2 per pyramid and 96 in2 per star.

10. Use the Pythagorean Theorem to find the length of the apothem. Let x represent the length of the apothem. c2 ¬a2 b2 92 ¬x2 62 81 ¬x2 36 45 ¬x2 35 ¬x The side measure of the base is 2x 2(35 ) 65 . Find the surface area.

Pages 663–665 Practice and Apply 7. T ¬1 2 P B

T ¬1 2 P B

2 ¬1 2 (7 7 7 7)(5) 7

¬1 )(9) (65 )2 2 (4 65

¬119 The surface area of the regular pyramid is 119 cm2. 8. Find the measure of the apothem of the base, x. 36 0 The central angle of the hexagon is 6 60. So, the angle formed by a radius and the apothem is 60 2 30.

¬421.5 The surface area of the regular pyramid is approximately 421.5 cm2. 11. Use the Pythagorean Theorem to find the slant height . c2 ¬a2 b2 2

2 82 ¬6 2

64 ¬9 2 55 ¬2 55 ¬ Find the measure of the apothem of the base, x. 36 0 The central angle of the pentagon is 5 72. So, the angle formed by a radius and the apothem 72 is 2 36.

30 x

2.25 in.

2.25 tan30 ¬ x 2.25 x ¬ tan 30

Find the surface area. 36 x

1 T ¬1 2 P 2 Px ¬1 2 P( x)

3 yd

2.2 5 ¬1 2 (6 4.5)6 tan30

tan36 ¬3x

¬133.6 The surface area of the regular pyramid is approximately 133.6 in2. 9. Use the Pythagorean Theorem to find the height of the triangular base. c2 ¬a2 b2

3 x ¬ tan36

Find the surface area. 1 T ¬1 2 P 2 Px ¬1 2 P( x)

2

82 ¬a2 8 2

3 ¬1 tan 36 2 (5 6)55

¬a2

64 16 48 ¬a2 43 ¬a Find the surface area.

¬173.2 The surface area of the regular pyramid is approximately 173.2 yd2. 12. Use the Pythagorean Theorem to find the slant height . c2 ¬a2 b2

T ¬1 2 P B 1 ¬1 ) 2 (3 8)(10) 2 (8)(43

2

3.2 2 6.42 ¬ 2

¬147.7 The surface area of the regular pyramid is approximately 147.7 ft2.

40.96 ¬2.56 2 38.4 ¬2 38.4 ¬ Find the measure of the apothem of the base, x. 36 0 The central angle of the hexagon is 6 60. So, the angle formed by a radius and the apothem is 60 2 30.

429

Chapter 12

Find the altitude of the triangular base. c2 ¬a2 b2 122 ¬a2 62 144 ¬a2 36 108 ¬a2 63 ¬a Find the surface area. T ¬1 2 P B

30 x

¬1 ) 1 ) 2 (3 12)(27 2 (12)(63

1.6 m

1.6 tan30 ¬ x 1. 6 x ¬ tan30

¬157.6 The surface area of the regular pyramid is approximately 157.6 cm2. 15. Use the Pythagorean Theorem to find the slant height . c2 ¬a2 b2

x ¬1.63 Find the surface area. 1 T ¬1 2 P 2 Px ¬1 2 P( x)

2

42 ¬2 4 2

¬1 1.63 ) 2 (6 3.2)(38.4

16 ¬2 4 12 ¬2 23 ¬ is also the altitude of the triangular base. Find the surface area. T ¬1 2 P B

¬86.1 The surface area of the regular pyramid is approximately 86.1 m2. 13. Use the Pythagorean Theorem to find the apothem, x. c2 ¬a2 b2 132 ¬122 x2 169 ¬144 x2 25 ¬x2 5 ¬x Find the side measure of the base, y. The central 36 0 angle of the pentagon is 5 72. So, the angle formed by the radius and the apothem is 72 2 36.

¬1 ) 1 ) 2 (3 4)(23 2 (4)(23

¬27.7 The surface area of the regular pyramid is approximately 27.7 ft2. 16. Use the Pythagorean Theorem to find the apothem, x. c2 ¬a2 b2 202 ¬52 x2 400 ¬25 x2 375 ¬x2 515 ¬x The side measure of the base is twice the apothem: 2x 1015 . Find the lateral area of the roof. L ¬1 2 P

36 5 in.

¬1 )(20) 2 (4 1015 y 2

¬1549.2 The area of the roof is approximately 1549.2 ft2. 17. Find the surface area of the first bottle. T ¬1 2 P B

y 2

tan36 ¬ 5 10 tan36 ¬y Find the surface area.

2 ¬1 2 (4 3)(4) 3

1 T ¬1 2 P 2 Px ¬1 2 P( x) 1 ¬2(5 10 tan36)(13 5)

¬33 Find the dimensions of the base of the second bottle. Let the side measure be x. T ¬1 2 P B

¬326.9 The surface area of the regular pyramid is approximately 326.9 in2. 14. Use the Pythagorean Theorem to find the slant height . c2 ¬a2 b2

2 T ¬1 2 (4x)(6) x

33 ¬12x x2 0 ¬x2 12x 33 Use the quadratic formula to find x. a ¬1 b ¬12 c ¬33

2

12 82 ¬2 2 2 64 ¬ 36 28 ¬2 27 ¬

Chapter 12

430

b b ac 4 x ¬ 2a 2

1 P L ¬\ 2 107 .25 ¬1 2 (4 214.5) cos53

12 12 33) 4(1)( ¬ 2(1) 2

¬76,452.5 The lateral area is approximately 76,452.5 m2. 21. Find the height of the pyramid using the Pythagorean Theorem. The apothem of the pyramid is half the length of its base, which is 1 2 12 ft: 2 6. c2 ¬a2 b2 102 ¬a2 62 100 ¬a2 36 64 ¬a2 8 ¬a The height of the solid is 12 8 20 ft. 22. Add the lateral areas of the pyramid and the cube. L ¬1 2 P Ph

¬2.3 or 14.3 The length of the side cannot be negative, so 14.3 is eliminated. The base of the second bottle is approximately 2.3 inches on each side. 18. Find the side measure of the base. 360,0 00 600 So, P 4(600) 2400 and the apothem is 60 0 2 300. Use the Pythagorean Theorem to find the slant height . c2 ¬a2 b2 2 ¬3002 3212 2 ¬193,041 ¬193,0 41 Find the lateral area. L ¬1 2 P

¬1 2 (4 12)(10) (4 12)(12)

¬1 41 2 (2400)193,0

¬816 The lateral area of the solid is 816 ft2. 23. The surface area of the solid is equal to the lateral areas of the pyramid and the cube plus the area of the cube’s base. T ¬1 2 P Ph B

¬527,237.2 The lateral area of the pyramid is approximately 527,237.2 ft2. 64 6 19. The apothem is half the length of the edge: 2 323. Use the Pythagorean Theorem to find the slant height . c2 ¬a2 b2 2 ¬3232 3502 2 ¬226,829 ¬226,8 29 Find the lateral area to find the area of the glass. L ¬1 2 P

2 ¬1 2 (4 12)(10) (4 12)(12) 12

¬960 The surface area of the solid is 960 ft2. 24. Each lateral face of the frustum is a trapezoid. Find the area of one face. A ¬1 2 h(b1 b2) ¬1 2 (b1 b2)

¬1 29 2 (4 646)226,8

¬1 2 (3)(2 4)

¬615,335.3 The area of the glass is approximately 615,335.3 ft2. 20. The apothem is half the length of the side of the 214.5 base: 2 107.25.

¬9 The lateral area is 4A 4(9) 36 yd2. 25. Find the surface area of the truncated cube. The area of the three intact faces is 3 in2. The truncation cuts three faces in half, leaving three triangles with a total area of 1.5 in2. The final face is an equilateral triangle. Use the Pythagorean Theorem to find the side measure of the triangle. c2 ¬a2 b2 c2 ¬12 12 c2 ¬2 c ¬2 Find the altitude of the triangle. c2 ¬a2 b2

53

107.25

2

2 (2 )2 ¬a2 2

Find the slant height. 107 .25 cos53 ¬

2 ¬a2 1 2

107 .25 ¬ cos53

1.5 ¬a2 1.5 ¬a Find the area of the triangle. A ¬1 2 bh

Find the lateral area.

)1.5 ¬1 2 (2 3 ¬ 2

431

Chapter 12

3 2 The surface area is 3 1.5 2 5.37 in . The surface area of the original cube is 6 square inches. The surface area of the truncated cube is approximately 5.37 square inches. Truncating the corner of the cube reduces the surface area by 0.63 square inch. 26. Sample answer: Pyramids are used as an alternative to rectangular prisms for the shapes of buildings. Answers should include the following. • We need to know the dimensions of the base and slant height to find the lateral area and surface area of a pyramid. • Sample answer: The roof of a gazebo is often a hexagonal pyramid. 27. D; T ¬1 2 P B

A ¬bh

153 ¬(22) 2

34.

35.

2

2 0 ¬1 2 (20)(10) 4

36.

¬125 cm2

37. 38. 39. 40.

1 28. A; x ⊗ y ¬ xy 1 1 ⊗ 3 ¬ 2 4 1 3 2 4 1 ¬ 2 3 4 4 1 ¬ 1 4

41. 42.

¬4

Page 665 Maintain Your Skills 29. T 2rh 2r2 2(7)(15) 2(7)2 967.6 The surface area is approximately 967.6 m2. 30. T ¬2rh 2r2

43.

2

d ¬2d 2h 22 2 ¬dh 1 2 d

2 ¬(22)(14) 1 2 (22)

44.

¬1727.9 The surface area is approximately 1727.9 cm2. 31. T 2rh 2r2 2(9)(23) 2(9)2 1809.6 The surface area is approximately 1809.6 yd2. 32. T L 2B Ph 2B (2 6 2 2.5)(14) 2(6)(2.5) 268 The surface area of the box is 268 in2. 33. P 2(22) 2(15) 44 30 74 Find the height. h ¬sin60 15

12-6 Surface Areas of Cones Page 668 Check for Understanding 1. Sample answer: vertex center of base

h ¬15sin60 153 h ¬ 2

Chapter 12

¬285.8 The perimeter is 74 ft and the area is approximately 285.8 ft2. P 24 2(32) 10 2(5) 6 (24 10 6) 122 A (32)(24) (5)(24 10 6) 808 The perimeter is 122 m and the area is 808 m2. P 17 12 (22 17) 9 22 (12 9 3 6) 3(6) 3 98 A (22)(12 9) (12)(22 17) 62 366 The perimeter is 98 m and the area is 366 m2. M F is reflected in line b, but F M lies on line b. So, the reflected image of F M is F M . The reflected image of J K in line a is G F . The reflected image of L in point M is point H. The reflected image of G M in line a is J M . False; each pair of opposite sides must be congruent. True; each pair of opposite sides is congruent. c2 ¬a2 b2 122 ¬82 b2 144 ¬64 b2 80 ¬b2 45 ¬b 8.9 ¬b The length is approximately 8.9 in. c2 ¬a2 b2 c2 ¬142 162 c2 ¬196 256 c2 ¬452 c ¬2113 c ¬21.3 The length is approximately 21.3 m. c2 ¬a2 b2 112 ¬a2 62 121 ¬a2 36 85 ¬a2 85 ¬a 9.2 ¬a The length is approximately 9.2 km.

432

2. The formula for the lateral area is derived from the area of a sector of a circle. If the vertex of the cone is not the center of this circle, the formula is not valid. 3. T r r2 (10)(17) (10)2 848.2 The surface area is approximately 848.2 cm2. 4. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬122 102 2 ¬144 100 2 ¬244 ¬261 T r r2 (10)(261 ) (10)2 804.9 The surface area is approximately 804.9 ft2. 5. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬82 82 2 ¬128 ¬82 T r r2 (8)(82 ) (8)2 485.4 The surface area is approximately 485.4 in2. 6. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2

9. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬92 92 2 ¬162 ¬92 T r r2 (9)(92 ) (9)2 614.3 The surface area is approximately 614.3 in2. 10. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 172 ¬r2 152 289 ¬r2 225 64 ¬r2 8 ¬r T r r2 (8)(17) (8)2 628.3 The surface area is approximately 628.3 ft2. 11. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 122 ¬r2 7.52 144 ¬r2 56.25 87.75 ¬r2 87.75 ¬r T r r2 (87.75 )(12) (87.75 )2 628.8 The surface area is approximately 628.8 m2. 12. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬2.62 6.42 2 ¬47.72 ¬47.72 T r r2 (2.6)47.72 (2.6)2 77.7 The surface area is approximately 77.7 yd2. 13. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 182 ¬r2 162 324 ¬r2 256 68 ¬r2 217 ¬r T r r2 (217 )(18) (217 )2 679.9 The surface area is approximately 679.9 in2. 14. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 19.12 ¬r2 8.72 364.81 ¬r2 75.69 289.12 ¬r2 289.1 2 ¬r T r r2 (289.1 2 )(19.1) (289.1 2 )2 1928.6 The surface area is approximately 1928.6 m2.

2

8.5 2 ¬552 2

¬3043. 0625 L ¬r 8.5 0625 ¬ 2 3043.

¬736.5 The lateral area is approximately 736.5 ft2.

Pages 668–670

Practice and Apply

7. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬52 122 2 ¬169 ¬13 T r r2 (5)(13) (5)2 282.7 The surface area is approximately 282.7 cm2. 8. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 102 ¬r2 82 100 ¬r2 64 36 ¬r2 6 ¬r T r r2 (6)(10) (6)2 301.6 The surface area is approximately 301.6 ft2.

433

Chapter 12

T r r2 2rh r( r 2h) (6)[213 6 2(6)] 475.2 The surface area is approximately 475.2 in2. 20. T r r2 2rh r( r 2h) (3)[5 3 2(5)] 169.6 The surface area is approximately 169.6 ft2. 21. Use the Pythagorean Theorem to find the slant height of the cone. c2 ¬a2 b2 2 ¬142 6.22 ¬234.4 4 T r 2rh r2 r( 2h r) (6.2)[234.4 4 2(28) 6.2] 1509.8 The surface area is approximately 1509.8 m2. 22. T ¬r

15. Solve the surface area equation for the slant height. T ¬r r2 T r2 ¬r T r2 ¬ r 2 ( 1 4.5) 1020 ¬ (14.5)

7.9 ¬ The slant height is approximately 7.9 m. 16. Solve the surface area equation for the slant height. T ¬r r2 T r2 ¬r T r2 ¬ r 2 (6.1) 293.2 ¬ (6.1)

9.2 ¬ The slant height is approximately 9.2 ft. 17. Use the surface area equation to solve for the radius. T ¬r r2 359 ¬r(15) r2 0

¬r2

¬d 2

359 15r

¬1 2 (42)(47.9)

Use the Quadratic Formula to solve for r. a ¬1 b ¬15

¬3160.1 The area of the canvas used is approximately 3160.1 ft2. 23. Find the radius. C ¬2r

359 c ¬

b ac b 4 r ¬ 2a 2

C ¬r 2 22 2 ¬r 11 ¬r

359 15 152 4(1) ¬ 2(1)

¬5.6 or 20.6 Since the radius of a circle cannot be negative, 20.6 is eliminated. So, the radius of the cone is approximately 5.6 ft. 18. Use the surface area equation to solve for the radius. T ¬r r2 523 ¬r(12.1) r2

Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2

11 2 2 ¬ 18

12 1 ¬ 2 324

Find the lateral area of all eight hats. 8L 8r

523 0 ¬r2 12.1r Use the Quadratic Formula to solve for r. a ¬1 b ¬12.1

¬1613.7 She will use approximately 1613.7 in2 of material. 24. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2

523 c ¬

b ac b 4 r ¬ 2a 2

12.1

52 3 4(1) 12.1 2

2

4 5 2 ¬242

¬ 2(1)

2

¬1082. 25 L ¬r

¬8.2 or 20.3 Since the radius of a circle cannot be negative, 20.3 is eliminated. So, the radius of the cone is approximately 8.2 m. 19. Use the Pythagorean Theorem to find the slant height of the cone. c2 ¬a2 b2 2 ¬42 62 2 ¬16 36 ¬213

Chapter 12

12 1 11 ¬8 2 324

4 5 1082. ¬ 25 2

¬2325.4 The lateral area is approximately 2325.4 ft2.

434

25. Use the equation for surface area to solve for the diameter. T ¬r r2 2 d T ¬d 2 2

29. Using the store feature on the calculator is the most accurate technique to find the lateral area. Rounding the slant height to either the tenths place or hundredths place changes the value of the slant height, which affects the final computation of the lateral area. 30. Never; the pyramid could be inscribed in the cone. 31. Sometimes; only when the heights have the same proportion. 32. As the altitude approaches zero, the slant height of the cone approaches the radius of the base. The lateral area approaches the area of the base. The surface area approaches twice the area of the base. 33. Sample answer: Tepees are conical shaped structures. Lateral area is used because the ground may not always be covered in circular canvas. Answers should include the following. • We need to know the circumference of the base or the radius of the base and the slant height of the cone. • The open top reduces the lateral area of canvas needed to cover the sides. To find the actual lateral area, subtract the lateral area of the conical opening from the lateral area of the structure. 34. B; L ¬r 91.5 ¬r(15) 6.1 ft ¬r 35. D; let the odd integers be x 4, x 2, and x. 3(x 4) ¬3 2x 3x 12 ¬3 2x x ¬15

1 2 T ¬1 2 d 4 d 1 2 500 ¬1 2 d(20) 4 d 2000 2 ¬40d d 2000 0 ¬d2 40d Use the Quadratic Formula to solve for d. a1 b 40 2000 c

b b ac 4 d ¬ 2a 2

2000 40 402 4(1) ¬ 2(1)

¬12 or 52 Since the diameter of a circle cannot be negative, 52 is eliminated. So, the diameter of light on stage is approximately 12 ft. 26. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬72 42 ¬65 ¬8.062257748 Use the store feature of the calculator to save . L r (4)(8.062257748) 101.3133 The lateral area of the cone is approximately 101.3133 in2. 27. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬72 42 ¬65 ¬8.1 L r (4)(8.1) 101.7876 The slant height and lateral area of the cone are approximately 8.1 in. and 101.7876 in2, respectively. 28. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬72 42 ¬65 ¬8.06 L r (4)(8.06) 101.2849 The slant height and lateral area of the cone are approximately 8.06 in. and 101.2849 in2, respectively.

Page 670


36. Use the Pythagorean Theorem to find the slant height. The apothem is half the length of the base’s side. c2 ¬a2 b2 2

14 9 2 2 2 853

¬733,1 59.25 P L ¬1 2 ¬1 59.25 2 (4 149)733,1

¬255,161.7 The lateral area is approximately 255,161.7 ft2. 37. T ¬2rh 2r2 563 ¬2r(9.5) 2r2 56 3 0 ¬r2 9.5r 2 Use the quadratic formula to solve for r. a1 b 9.5 56 3 c 2 2 4ac b b r ¬ 2a

56 3 9.5 9.52 4(1) 2 ¬ 2(1)

¬5.8 or 15.3

435

Chapter 12

44. Since the radius M K is perpendicular to the chord G F , it bisects the chord. So, LG is equal to FL, or 24. 45. Since the radius M P is perpendicular to the chord J H , it bisects the chord and its arc. So, mPJ is equal to mHP , or 45. 46. Since the radius M P is perpendicular to the chord J H , it bisects the chord and its arc. So, mHJ is twice mHP , or 90. 47. Let x represent the geometric mean.

Since the radius of a circle cannot be negative, 15.3 is eliminated. So, the radius is approximately 5.8 ft. 38. T ¬2rh 2r2 185 ¬2r(11) 2r2 18 5 0 ¬r2 11r 2 Use the Quadratic Formula to solve for r. a1 b 11 18 5 c 2

x 7 x ¬ 6 3

2 4ac b b r ¬ 2a

x2 ¬441 x ¬21 48. Let x represent the geometric mean.

18 5 11 112 4(1) 2 ¬ 2(1)

¬2.2 or 13.2 Since the radius of a circle cannot be negative, 13.2 is eliminated. So, the radius is approximately 2.2 m. 39. T ¬2rh 2r2 470 ¬2r(6.5) 2r2

x 8 x ¬ 1 8

x2 ¬144 x ¬12 49. Let x represent the geometric mean. 16 x x ¬ 4 4

47 0 0 ¬r2 6.5r 2 Use the Quadratic Formula to solve for r. a1 b 6.5

x2 ¬704 x ¬811 26.5 50. C 2r 2(6) 37.7 52. C d ¬(18) 56.5 54. C d (19.8) 62.2

47 0 c 2

2 4ac b b r ¬ 2a

6.5

47 0 4(1) 2 6.5 2

¬ 2(1) ¬6.0 or 12.5 Since the radius of a circle cannot be negative, 12.5 is eliminated. So, the radius is approximately 6.0 yd. 40. T ¬2rh 2r2 951 ¬2r(14) 2r2

Page 670

Practice Quiz 2

1. Use the Pythagorean Theorem to find the slant height. The apothem is equal to half the base’s edge. c2 ¬a2 b2 2 ¬62 102 ¬234

95 1 0 ¬r2 14r 2 Use the Quadratic Formula to solve for r. a1 b 14 95 1 c 2

T ¬1 2 P B

2 4ac b b r ¬ 2a

¬1 ) 122 2 (4 12)(234

¬423.9 The surface area is approximately 423.9 cm2. 2. Find the apothem of the base, x. The central angle 36 0 of the hexagon is 6 60. So, the angle formed 60 by the radius and the apothem is 2 30.

95 1 14 142 4(1) 2 ¬ 2(1)

¬7.2 or 21.2 Since the radius of a circle cannot be negative, 21.2 is eliminated. So, the radius is approximately 7.2 cm. 41. Since the radius M K is perpendicular to the chord G F , it bisects the chord. So, FG is twice FL, or 48. 42. Since the radius M P is perpendicular to the chord J H , it bisects the chord. So, NJ is half of HJ, or 24. 43. Since the radius M P is perpendicular to the chord J H , it bisects the chord. So, HN is half of HJ, or 24.

Chapter 12

51. C ¬d ¬(8) ¬25.1 53. C ¬2r ¬2(8.2) ¬51.5 55. C ¬2r ¬2(4.1) ¬25.8

30 x 2 in.

436

tan30 ¬2x 2 x ¬ tan 30

3. Use the Pythagorean Theorem to find AB. AB2 ¬AC2 BC2 AB2 ¬92 122 AB2 ¬81 144 AB2 ¬225 AB ¬15 4. Use the Pythagorean Theorem to find AC. AB2 ¬AC2 BC2 152 ¬AC2 102 225 ¬AC2 100 125 ¬AC2 11.2 ¬AC 5. If Q is a point on C, then AQ is equal to the radius of the sphere, and thus, AB. So, AQ 18. 6. T 4r2 4(6.8)2 581.1 The surface area is approximately 581.1 in2. 7. Find the radius. C ¬2r 8 ¬2r 4 ¬r 2 2 T ¬1 2 (4r ) r

x ¬23 Find the surface area. 1 T ¬1 2 P 2 Px ¬1 2 P( x) ¬1 ) 2 (6 4)(11 23

¬173.6 The surface area is approximately 173.6 in2. 3. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬32 122 ¬317 T r r2 (3)(317 ) (3)2 144.9 The surface area is approximately 144.9 ft2. 4. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬62 22 ¬210 T r r2 (6)(210 ) (6)2 232.3 The surface area is approximately 232.3 m2. 5. Use the equation for the lateral area to solve for the slant height. L ¬r

¬2(4)2 (4)2 ¬150.8 The surface area is approximately 150.8 cm2. 8. Find the radius. A ¬r2 18.1 ¬r2 18 .1 ¬r

T ¬4r2

18 .1

¬4

¬L r

2

¬72.4 The surface area is approximately 72.4 m2. 9. T 4r2 4(4.75)2 283.5 The surface area is approximately 283.5 in2.

123 ¬ (1 0)

¬3.9 The slant height is approximately 3.9 in.

12-7 Surface Areas of Spheres Pages 674–676 Page 672 Geometry Activity: Surface Area of a Sphere 1. 2. 3.

1 4

r2 The surface area of a sphere is 4 times the area of the great circle.

Page 674

Practice and Apply

10. Use the Pythagorean Theorem to find PR. PR2 ¬PT 2 RT 2 PR2 ¬42 32 PR2 ¬16 9 PR2 ¬25 PR ¬5 11. Use the Pythagorean Theorem to find PR. PR2 ¬PT 2 RT 2 PR2 ¬32 82 PR2 ¬9 64 PR2 ¬73 PR ¬8.5 12. Use the Pythagorean Theorem to find PT. PR2 ¬PT 2 RT 2 132 ¬PT 2 122 169 ¬PT 2 144 25 ¬PT 2 5 ¬PT


1. Sample answer:

2. Tim; the surface area of a hemisphere is half of the surface area of the sphere plus the area of the great circle.

437

Chapter 12

¬290.3 The surface area is approximately 290.3 ft2. 23. Find the radius. A ¬r2 814.3 ¬r2

13. Use the Pythagorean Theorem to find PT. PR2 ¬PT 2 RT 2 172 ¬PT 2 152 289 ¬PT 2 225 64 ¬PT 2 8 ¬PT 14. If X is a point on T, then PX is equal to the radius of the sphere, and thus, PR. So, PX 9.4. 15. If Y is a point on T, then PY is equal to the radius of the sphere, and thus, PR. So, PY 12.8. 16. Use the Pythagorean Theorem to find the radius of the charcoal rack. c2 ¬a2 b2 112 ¬r2 52 121 ¬r2 25 96 ¬r2 Find the difference in the areas. (11)2 r2 121 96 25 78.5 The difference in the areas is 25 78.5 in2. 17. T 4r2 4(25)2 7854.0 The surface area is approximately 7854.0 in2. 18. T 4r2 4(14.5)2 2642.1 The surface area is approximately 2642.1 cm2. 19. T ¬4r2

814.3 ¬r

T ¬4r2

814.3

¬4

2

¬3257.2 The surface area is 3257.2 m2. 24. Find the radius. A ¬r2 227.0 ¬r2 227.0 ¬r 2 2 T ¬1 2 (4r ) r 2 ¬3r

227.0

¬3

2

¬681.0 The surface area is 681.0 km2. 25. True; a great circle is formed by the intersection of a plane with a sphere such that the plane contains the center of the sphere, so they have the same center and radii. 26. False; two great circles will intersect at two points.

2

¬4d 2

¬d2 ¬(450)2 ¬636,172.5 The surface area is approximately 636,172.5 m2. 20. T ¬4r2

27. True; two spheres can intersect in a point or a circle, regardless of the lengths of their radii. So the statement is true.

2

¬4d 2

¬d2 ¬(3.4)2 ¬36.3 The surface area is approximately 36.3 ft2. 21. Find the radius. C ¬2r 40.8 ¬2r

28. True; a chord that contains the center of a sphere is a diameter of a sphere. The diameter is the width of a sphere, and thus, is the longest chord. 29. True; when two spheres are tangent they intersect in one point. 30. Pole to pole: T ¬4r2

20 .4 ¬r 2 2 T ¬1 2 (4r ) r

¬3r2

2

¬4d 2

¬d2 ¬(7899.83)2 ¬196,058,359.3 mi2 Equator: T (7926.41)2 197,379,906.2 mi2

2

20 .4 ¬3

¬397.4 The surface area is approximately 397.4 in2. 22. Find the radius. C ¬2r 30.2 ¬2r 15 .1 ¬r

T ¬4r2

2

15 .1 ¬4

Chapter 12

438

31. Find the mean diameter.

40. The distance between opposite corners of the cube is equal to the diameter of the sphere. Use the Pythagorean Theorem to find the diagonal of a cube face if the side is x. c2 ¬a2 b2 c2 ¬x2 x2 c ¬x2 Now, find the opposite corner distance. c2 ¬a2 b2 c2 ¬x2 (x2 )2 2 2 c ¬3x c ¬x3 3 x The radius is half this, so r 2 , where x is the length of each side of the cube. 41. None; every line (great circle) that passes through X will also intersect g. All great circles intersect. 42. Sample answer: Sports equipment manufacturers use the surface area of spheres to determine the amount of material to cover the balls for different sports. Answers should include the following. • The surface area of a sphere is four times the area of the great circle of the sphere. • Racquetball and basketball are other sports that use balls. 43. A; the distance between opposite corners of the rectangular solid is equal to the diameter of the sphere. Use the Pythagorean Theorem to find the diagonal of the 4 ⊗ 5 face. c2 ¬a2 b2 c2 ¬42 52 c ¬41 Now, find the opposite corner distance. c2 ¬a2 b2 c2 ¬72 (41 )2 2 c ¬90 c ¬310 The radius is half this, so

7899.83 7926.41 7913.12 2

The diameter of the atmosphere is 200 miles longer than the mean value: 8113.12 mi. T ¬4r2 2

¬4d 2

¬d2 ¬(8113.12)2 ¬206,788,161.4 mi2 32. Find the mean diameter. 7899.83 7926.41 7913.12 2

T 4r2, so 0.75T 0.75(4r2) 0.75d2 is the surface area of the water. 0.75(7913.12)2 147,538,933.4 mi2 1 (4r2) r2 33. T ¬ 2 2

2

d ¬2d 2 2 2 1 2 ¬1 2 d 4 d 2 ¬3 4 (13)

¬398.2 The surface area is approximately 398.2 ft2. 34. T 4r2, so if the radius is twice as large, 4(2r)2 16r2, and the ratio is r2 16 4, or 4 : 1. 4r2 35. Let T2 ¬1 2 T1. Then 1 2 4r2 ¬2(4r21) 2 r22 ¬1 2 r1 r1 r2 ¬ 2 2 r2 ¬2 r1 2 The ratio is 2 : 1.

36. T 4r2, so if the radius is three times as large, 4(3r)2 36r2, and the ratio is

10 3 r 2 4.74 in.

r2 36 9, or 9 : 1. 4r2

37. T ¬4r2

2 7 2 ¬x 1 44. C; x 2 7 ¬x 1 x x2 7 ¬(x 1)2 x2 7 ¬x2 2x 1 6 ¬2x 3 ¬x

2

¬4d 2

¬d2 12 mi : d2 (12)2 144 452.4 20 mi : d2 (20)2 400 1256.6 The surface area can range from 452.4 to 1256.6 mi2. 38. T ¬4r2 2 ¬4d 2

Page 676


45. Use the Pythagorean Theorem to find the radius of the base. c2 ¬a2 b2 192 ¬r2 132 192 ¬r2 83 ¬r T r r2 (83 )(19) (83 )2 1430.3 The surface area is approximately 1430.3 in2.

¬d2 ¬(7)2 ¬153.9 The surface area is approximately 153.9 mi2. 39. The side length of the cube is equal to the diameter of the sphere, so the radius of the sphere is half the side of the cube.

439

Chapter 12

46. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬72 102 ¬149 T r r2 (7)149 (7)2 422.4 The surface area is approximately 422.4 m2. 47. T r r2 (4.2)(15.1) (4.2)2 254.7 The surface area is approximately 254.7 cm2. 48. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2

53. Find the radius squared. (x h)2 (y k)2 ¬r2 [3 (2)]2 (2 7)2 ¬r2 52 (5)2 ¬r2 25 25 ¬r2 50 ¬r2 The equation of the circle is (x 2)2 (y 7)2 50. 54. Find the center. 2 6 h 2 4

8 5 k 3 2 2

Find the radius squared. 2

2 (2 4)2 5 3 2 ¬r 2

1 3 2 (2)2 2 ¬r

2

11 .2 2 ¬7.42 2

18 5 2 4 ¬r

¬86.12 T ¬r r2 2 d ¬d 2 2

The equation of the circle is 2

18 5 (x 4)2 y 3 2 4 .

1 2 ¬1 2 d 4 d

Page 677 Geometry Activity: Locus and Spheres

2 ¬1 1 2 (11.2)86.12 4 (11.2)

1.

¬261.8 The surface area is approximately 261.8 ft2.

15

5

5

49. T ¬1 2 P B 2 ¬1 2 (4 19)(16) 19

¬969 The surface area is 969 yd2. 50. The apothem is half the base, or 6 feet. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬62 (13)2 ¬205

2. 3. 4.

T ¬1 2 P B ¬1 122 2 (4 12)205

5.

¬487.6 The surface area is approximately 487.6 ft2.

6. 7.

51. T ¬1 2 P B 2 ¬1 2 (4 11)(24) 11

¬649 The surface area is 649 cm2. 52. The diameter of the fabric required is 9 2(3) 15 in. A ¬r2

8.

2

¬d 2

The locus of all points in space at a specific distance from a given point is a sphere. Thus, for this problem, the locus of points is two spheres each with a radius of 5 units with centers that are endpoints of the given line segment. Yes, the radii are congruent. Each sphere has a radius of 5 units and a diameter of 10 units. The segment is 25 units long and the radii of the spheres are 5 units. So, the spheres are 15 units apart on the given segment. The spheres intersect at a plane. The intersection of a plane and a sphere is a circle or a point. So, the intersection is a circle. A circle is a locus of points on a plane. The intersection is the set of all points equidistant from the midpoint of the given line segment in the plane containing the perpendicular bisector of the given line segment. The particles from an explosion disperse in a spherical pattern. Since the explosion is at ground level, the locus of points describing the dispersion of particles is a hemisphere with a radius of 300 ft.

2 ¬1 4 (15)

¬176.7 The area of fabric needed is approximately 176.7 in2.

Chapter 12 Study Guide and Review Page 678 Vocabulary and Concept Check 1. d 5. a 8. g

Chapter 12

440

2. i 6. j 9. c

3. b 7. e 10. f

4. h

T ¬1 2 P B

Pages 678–682 Lesson-by-Lesson Review 11. The solid is a cylinder. Bases: F and G There are no faces, edges, or vertices. 12. The solid is a rectangular prism. Bases: rectangle WXYZ and rectangle STUV Faces: rectangles WXYZ, STUV, WXTS, XTUY, YUVZ, and WZVS Edges: W X , X Y , Y Z , Z W , S T , T U , U V , V S , W S , X T , U Y , and Z V Vertices: S, T, U, V, W, X, Y, and Z 13. The solid is a triangular prism. Base: BCD Faces: ABC, ABD, ACD, and BCD Edges: A B , B C , A C , A D , B D , and C D Vertices: A, B, C, and D 14. Use the Pythagorean Theorem to find the hypotenuse of the triangular base. c2 ¬a2 b2 c2 ¬32 42 c2 ¬25 c ¬5

2 ¬1 2 (4 10)(12) 10

¬340 The surface area is 340 units2. 16.

T 6s2 6(4)2 96 The surface area is 96 units2. 17. Use the Pythagorean Theorem to find the measure of the third side of the triangular base. c2 ¬a2 b2 62 ¬42 b2 36 ¬16 b2 20 ¬b2 25 ¬b

T ¬Ph 2B ¬(3 4 5)(6) 2 1 2 34

¬84 The surface area is 84 units2. 15. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2

1 0 132 ¬2 2

169 ¬2 25 144 ¬2 12 ¬

T ¬Ph 2B ¬(4 6 25 )(8) 2 1 2 4 25

¬133.7 The surface area is approximately 133.7 units2.

12

18.

13

10

T Ph 2B (2 2 2 4)(5) 2(2)(4) 76 The surface area is approximately 76 units2.

441

Chapter 12

25. T 2rh 2r2 2(4)(58) 2(4)2 1558.2 The surface area is approximately 1558.2 mm2. 26. T ¬2rh ¬2r2

19. Use the Pythagorean Theorem to find the measure of the fourth side of the trapezoidal base. c2 ¬a2 b2 c2 ¬42 (8 5)2 c2 ¬25 c ¬5

2

d ¬2d 2 h 2 2 2 ¬dh 1 2 d

2 ¬(4)(8) 1 2 (4)

¬125.7 The surface area is approximately 125.7 km2. 27. T ¬1 2 P B 2 ¬1 2 (4 8)(15) 8

¬304 The surface area is 304 units2. 28. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2

1 0 132 ¬2 2

169 ¬2 25 144 ¬2 12 ¬ The central angle of the pentagon measures 36 0 5 or 72. So, the angle formed by a radius and 72 the apothem is 2 or 36. Find the apothem, x.

T ¬Ph 2B ¬(4 5 5 8)(8) 2 1 2 (4)(5 8)

20.

21.

22.

23.

¬228 The surface area is 228 units2. Use the Pythagorean Theorem to find the hypotenuse of the triangular base. c2 ¬a2 b2 c2 ¬152 202 c2 ¬625 c ¬25 L Ph (15 20 25)(18) 1080 The lateral area is 1080 units2. L Ph (3 5 6 10)(3) 72 The lateral area is 72 units2. L Ph (3 8 7 5)(4) 92 The lateral area is 92 units2. T ¬2rh 2r2

36 x 5

tan36 ¬5x 5 x ¬ tan36 1 T ¬1 2 P 2 Px ¬1 2 P( x) 5 ¬1 2 (5 10)12 tan36

¬472.0 The surface area is approximately 472.0 units2. 29. Use the Pythagorean Theorem to find the height of the triangular base. c2 ¬a2 b2

2

d ¬2d 2h 22

2

52 ¬h2 5 2

2 ¬dh 1 2 d

25 ¬h2 6.25 18.75 ¬h

2 ¬(4)(12) 1 2 (4)

¬175.9 The surface area is approximately 175.9 in2. 24. T 2rh 2r2 2(6)(8) 2(6)2 527.8 The surface area is approximately 527.8 ft2.

Chapter 12

1 T ¬1 2 P 2 bh 1 ¬1 2 (3 5)(3) 2 (5)18.75

¬33.3 The surface area is approximately 33.3 units2.

442

2 2 37. T ¬1 2 (4r ) r

30. T r r2 (5)(18) (5)2 361.3 The surface area is approximately 361.3 mm2. 31. Use the Pythagorean Theorem to find the radius of the base. c2 ¬a2 b2 52 ¬42 r2 25 ¬16 r2 9 ¬r2 3 ¬r T r r2 (3)(5) (3)2 75.4 The surface area is approximately 75.4 yd2. 32. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬32 72 2 ¬9 49 ¬58 T r r2 (3)58 (3)2 100.1 The surface area is approximately 100.1 in2. 33. T ¬4r2

¬3r2 ¬3(16)2 ¬2412.7 The surface area is approximately 2412.7 ft2. 38. T ¬4r2 2

¬4d 2

¬d2 ¬(5)2 ¬78.5 The surface area is approximately 78.5 m2. 39. Find the radius squared. A ¬r2 220 ¬r2 220 2 ¬r

T ¬4r2 220 ¬4

¬880 The surface area is 880 ft2. 40. Find the radius squared. A ¬r2 30 ¬r2 30 2 ¬r 2 2 T ¬1 2 (4r ) r

2 ¬4d 2

¬d2 ¬(18.2)2 ¬1040.6 The surface area is approximately 1040.6 ft2.

¬3r2 30 ¬3

¬90 The surface area is 90 cm2.

2 2 34. T ¬1 2 (4r ) r

¬3r2 ¬3(3.9)2 ¬143.4 The surface area is approximately 143.4 cm2. 35. Find the radius squared. A ¬r2 121 ¬r2

Chapter 12 Practice Test Page 683 1. c 2. a 3. b 4. The solid is a rectangular prism. Bases: rectangles PQRS and TUVW Faces: rectangles PQRS, TUVW, SPUT, QRWV, STWR, and PUVQ Edges: P S , Q R , V W , U T , P U , S T , R W , Q V , P Q , S R , V U , and T W Vertices: P, Q, R, S, T, U, V, and W 5. The solid is a sphere. 6. The solid is a cone. Base: F Vertex: H

121 2 ¬r 2 2 T ¬1 2 (4r ) r

¬3r2 121 ¬3

¬363 The surface area is 363 mm2. 36. Find the radius squared. A ¬r2 218 ¬r2 218 2 ¬r

T ¬4r2 218 ¬4

¬872 The surface area is 872 in2.

443

Chapter 12

11. L Ph (5 3 4 7 4)(8) 184 The lateral area is 184 units2. 12. T 2rh 2r2 2(8)(22) 2(8)2 1508.0 The surface area is approximately 1508.0 ft2. 13. T 2rh 2r2 2(3)(2) 2(3)2 94.2 The surface area is approximately 94.2 mm2. 14. T 2rh 2r2 2(78)(100) 2(78)2 87,235.7 The surface area is approximately 87,235.7 m2. 15. Use the Pythagorean Theorem to find the slant height of the tetrahedron. c2 ¬a2 b2

7.

T Ph 2B (2 4 2 6)(3) 2(4)(6) 108 The surface area is 108 units2. 8. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2

(226 )2 ¬2 4 2

2

62 ¬2 6 2

104 ¬2 4 100 ¬2 10 ¬

2 26

36 ¬2 9 27 ¬2 33 ¬ 36 0 The central angle of the triangular base is 3 or 120. So, the angle formed by a radius and the 12 0 apothem is 2 or 60. Find the apothem, x.

4

60 x 3

T ¬1 2 P B

tan60 ¬3x

2 ¬1 2 (4 4)(10) 4

3 x ¬ tan 60

¬96 The surface area is 96 units2. 9. L(3 5 base) Ph (2 3 2 5)(6) 96 L(3 6 base) (2 3 2 6)(5) 90 L(6 5 base) (2 6 2 5)(3) 66 The lateral areas are 96 units2 (3 5 base), 90 units2 (3 6 base), and 66 units2 (6 5 base). 10. Use the Pythagorean Theorem to find the hypotenuse. c2 ¬a2 b2 c2 ¬152 202 c2 ¬625 c ¬25 L Ph (15 20 25)(8) 480 The lateral area is 480 units2.

x ¬3 Use the Pythagorean Theorem with the apothem and slant height to find the height of the tetrahedron. c2 ¬a2 b2 (33 )2 ¬(3 )2 b2 27 ¬3 b2 24 ¬b2 4.9 ¬b The height is approximately 4.9 8 12.9 units. 16. Use the Pythagorean Theorem to find the slant height of the tetrahedron. c2 ¬a2 b2 2 62 ¬2 6 2 36 ¬2 9 27 ¬2 33 ¬ L ¬Lprism Ltetrahedron ¬Ph 1 2 P ¬(3 6)(8) 1 ) 2 (3 6)(33

¬190.8 The lateral area is approximately 190.8 units2.

Chapter 12

444

17. Use the Pythagorean Theorem to find the slant height of the tetrahedron. The slant height is the same as the altitude of the base. c2 ¬a2 b2

24. The area of the plastic is equal to the area of the prism minus the area of the 12 ft by 25 ft rectangular face. Use the Pythagorean Theorem to find the height of the triangular part of the base. c2 ¬a2 b2

2

62 ¬2 6 2

36 ¬2 9 27 ¬2 33 ¬ T ¬Ph 1 2 P B

2

12 102 ¬a2 2

100 ¬a2 36 64 ¬a2 8 ¬a T ¬Ph 2B (12)(25)

¬(3 6)(8) 1 ) 1 2 (3 6)(33 2 6 33

18.

19.

20.

21.

22.

¬206.4 The surface area is approximately 206.4 units2. Use the Pythagorean Theorem to find the slant height. c2 ¬a2 b2 2 ¬242 72 2 ¬625 ¬25 T r r2 (7)(25) (7)2 703.7 The surface area is approximately 703.7 units2. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 42 ¬32 r2 16 ¬9 r2 7 ¬r2 7 ¬r T r r2 (7 )(4) (7 )2 55.2 The surface area is approximately 55.2 units2. T r r2 (7)(12) (7)2 417.8 The surface area is approximately 417.8 units2. T 4r2 4(15)2 2827.4 The surface area is approximately 2827.4 in2. T ¬4r2

¬(2 10 2 8 12)(25) 2 (8)(12) 1 2 12 8 300

¬1188 The amount of plastic needed is 1188 ft2. 25. D; T ¬6s2 150 ¬6s2 25 ¬s2 5 ¬s The length of each edge is 5 cm.

Chapter 12 Standardized Test Practice Pages 684–685 3x 16 ¬2x 9 x ¬25 [3(25) 16] ¬59 D; the change in x is 6 0 6 units. D; The change in y is 9 1 8 units. So, the other endpoint has coordinates (10 6, 6 8) (4, 2) or (10 6, 6 8) (16, 14). C B; the relative length of each side corresponds to the relative measure of its opposite angle. mC 180 70 48 62 C A is longest, A B is in the middle, and B C is shortest. B; use the Pythagorean Theorem to find the length of A B . AC2 ¬BC2 AB2 122 ¬52 AB2 144 ¬25 AB2 119 ¬AB2 10.9 ¬AB The length of A B is approximately 10.9 in.

1. D;

2.

3. 4.

5.

2

¬4d 2

¬d2 ¬(14)2 ¬615.8 The surface area is approximately 615.8 m2. 23. Find the radius squared. A ¬r2 116 ¬r2

N 2 6. B; A ¬ r 360

2

N d ¬ 2 360

116 2 ¬r

N 2 ¬ 14 40 d

T ¬4r2 116 ¬4

120 360 2 ¬ 1440 (18)

¬464 The surface area is 464 ft2.

¬54 7. C; for example, a tetrahedron is a Platonic Solid but it is not a prism.

445

Chapter 12

8. B; use the Pythagorean Theorem to find the height of the triangular bases. c2 ¬a2 b2

14a. Sample answer:

2

22 ¬a2 2 2

4 ¬a2 1 3 ¬a2 3 ¬a T ¬Ph 2B

15 ft

¬(3 2)(4) 2 1 2 2 3

¬27 The surface area is approximately 27 cm2. 9. A; T ¬4r2 2 ¬4d 2

18 in.

¬d2 ¬(4)2 ¬50 The surface area is approximately 50 ft2. 10. Let y be the height of the opposite side of the right triangle.

14b. Change the diameter from inches to feet. There 1 8 are 12 inches in 1 foot, so 18 inches 12 or 1.5 feet. L ¬2rh ¬2d 2 h

¬dh ¬(1.5)(15) ¬71 The lateral area is approximately 71 ft2. 14c. T ¬2rh 2r2

y

tan58 ¬ 47

47tan58 ¬y 75 ¬y So, the height of the tree is approximately 75 5 80 ft.

2

d ¬2d 2h 22

11. A ¬1 2 bh

2 ¬dh 1 2 d

¬1 2 (12x 2x)(8x 2x) 1 ¬2(10x)(6x)

2 ¬(1.5)(15) 1 2 (1.5)

¬74 The surface area is approximately 74 ft2. 15a. T ¬r r2

¬30x2 The area is 30x2 units2. 12. area of deck area of rectangle area of semicircle 2 w 1 2 r

2

d ¬d 2 2

1 2 ¬1 2 d 4 d 2 1 ¬1 2 (8)(7) 4 (8)

2

26 6 (26)(16) 1 2 2

¬138 The surface area is approximately 138 in2. 15b. T ¬2rh 2r2

259 The area of the deck is approximately 259 ft2. 13. Find the apothem, x. The central angle of the pentagonal base is 36 0 5 or 72. So, the angle formed by a radius and 72 the apothem is 2 or 36.

2

d ¬2d 2h 22 2 ¬dh 1 2 d

2 ¬(8)(22) 1 2 (8)

¬653 The surface area is approximately 653 in2. 15c. T ¬r 2rh r2 2

d d ¬d 2 22h 2 1 2 ¬1 2 d dh 4 d

36 x

2 1 ¬1 2 (8)(7) (8)(22) 4 (8)

4.5 cm 4.5 tan36 ¬ x 4.5 x ¬ tan 36 P 1Px T ¬1 2 2 4.5 (5 9)(15) 1(5 9) ¬1 tan 36 2 2

¬691 The surface area is approximately 691 in2.

¬476.9 The surface area is approximately 476.9 cm2. Chapter 12

446

Chapter 13 Volume Page 687 1.

8.

Getting Started

Solve for a. a2 144 ¬169 a2 ¬25 a ¬25 a ¬5 a2

122

132

30

2

2. 43 b2 82 Solve for b. 48 b2 ¬64 b2 ¬16 b ¬ 16 b ¬4

7

3.5

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The shorter leg of the triangle is 1 2 (7) or 3.5. The apothem is the longer leg of the triangle or 3.53 . perimeter 7 6 42

2

3. a2 a2 32 Solve for a. 2a2 ¬18 a2 ¬9 a ¬ 9 a ¬3 4. b2 3b2 192 Solve for b. 4b2 ¬192 b2 ¬48 b ¬ 48 b ¬4 3 5. 256 72 c2 Solve for c. 256 49 ¬c2 305 ¬c2 c ¬ 305 6. 144 122 c2 Solve for c. 144 144 ¬c2 288 ¬c2 288 ¬c c ¬122 7.

Area: A 1 2 Pa 1 2 (42)3.53

127.3 The area is approximately 127.3 ft2. 9.

C 45 13.4

A B D Apothem: The central angles of the octagon are 36 0 all congruent, so mACB D is an 8 or 45. C apothem of the octagon. It bisects ACB and is a perpendicular bisector of A B . So mACD 22.5. Since the side of the octagon has measure 13.4, AD 6.7. 6. 7 tan22.5° ¬ CD 6.7 CD ¬ tan 22.5°

¬16.175 perimeter (13.4)(8) 107.2

30 7.2

Area: A ¬1 2 Pa ¬1 2 (107.2)(16.175)

3.6

¬867.0 The area is approximately 867.0 mm2.

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. (7.2) or 3.6. The shorter leg of the triangle is 1 2 The apothem is the longer leg of the triangle or 3.63 . perimeter (7.2)(6) 43.2 Pa Area: A 1 2

(43.2)3.63 1 2

134.7 The area is approximately 134.7 cm2.

447

Chapter 13

10.

17. Let A be (x1, y1) in the Midpoint Formula.

1 2 x

1 y 2

W(10, 10) W 2 , 2

Write two equations to find the coordinates of B.

C

1x 2

45

A B D Apothem: The central angles of the octagon are 36 0 all congruent, so mACB D is an 8 or 45. C apothem of the octagon. It bisects ACB and is a perpendicular bisector of A B . So mACB 22.5. Since the side of the octagon has measure 10, AD 5.

x (2) 2

1 0

Page 688 Geometry Activity: Volume of a Rectangular Prism

¬482.8 The area is approximately 482.8 square in2. 11. (5b)2 (5b)(5b) (5)(5)(b)(b) 25b2

1. 12 cubes in top layer 12 cubes in bottom layer 24 cubes 2. The prism is 4 cubes long, 3 cubes wide, and 2 cubes high. 4 3 2 24. 3. They are the same. 4. See students’ work. 5. V wh

2 n n 12. n 4 4 4

n n 44 2

n 1 6 x 2 3 x 3 x 13. 3 4y 4y 4y

Page 691

3x 3x 4y 4y


1. Sample answers: cans, roll of paper towels, and chalk; boxes, crystals, and buildings 2. Julia; Che did not multiply 33 correctly. 3. V Bh 1 2 (8)(12)(6) 288 The volume of the prism is 288 cm3. 4. The diameter of the base, the diagonal, and the lateral edge form a right triangle. Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 h2 82 ¬172 h2 64 ¬289 h2 ¬225 h ¬15 Now find the volume. V r2h (42)(15) 754.0 The volume is approximately 754.0 in3. 5. V r2h (7.52)(18) 3180.9 The volume is approximately 3180.9 mm3.

3 3 xx 44yy 2

9x 16y2 4y 4y 7 7 4y 4y 77 44yy 77 16y2 49

14.

15. Let A be (x1, y1) and B be (x2, y2). The coordinates of the midpoint are 0 (5) 1 4

1 2 1 2 , 2, 2 2 2 3 5 2 , 2 or (2.5, 1.5)

16. Let A be (x1, y1) and B be (x2, y2). The coordinates of the midpoint are 5 (3) 0 6

1 2 1 2 , 2, 2 2 2

(1, 3)

Chapter 13

y 2 2

1 0 ¬

13-1 Volumes of Prisms and Cylinders

Area: A ¬1 2 Pa 1 ¬2(80)(12.07)

y y

0 x1 2 0 ¬y1 2 2 x1 2 ¬y1 The coordinates of A are (2, 2).

¬12.07

x x

y 2 2

Write two equations to find the coordinates of A.

perimeter (10)(8) 80

y y

20 ¬1 y2

x 2(2)

5 CD ¬ tan22.5°

x x

20 1 x2

1 1 W(0, 0) W ,

5 tan22.5° ¬ CD

2

10 ¬2

19 x2 21 ¬y2 The coordinates of B are (19, 21). 18. Let B be (x2, y2) in the Midpoint Formula.

10

4y 7

1 y 2

10 2

448

6. Use the formula for the volume of a rectangular prism. V Bh (12)(12)(14) 2016 The volume of the prism is 2016 ft3.

13. Find the volume of the oblique prism using the formula for a rectangular prism. V Bh (2.5)(3.5)(3.2) 28 The volume of the oblique prism is 28 ft3. 14. Find the volume of the oblique prism using the formula for a rectangular prism. V Bh (55)(35)(30) 57,750 The volume of the oblique prism is 57,750 m3. 15. Find the volume of the oblique cylinder using the formula for a right cylinder. V r2h (13.22)(27.6) 15,108.0 The volume is approximately 15,108.0 mm3. 16. Find the volume of the oblique cylinder using the formula for a right cylinder. V r2h (2.62)(7.8) 165.6 The volume is approximately 165.6 yd3. 17. V ¬ r2h Solve for r. 615.8 ¬ r2(4) 49 ¬r2 7 ¬r The diameter is about 2(7) or 14 m. 18. V ¬Bh 1152 ¬64h 18 ¬h The lateral edge length is 18 in. 19. The solid is a rectangular prism with 4, w 3, h 2. V Bh (4)(3)(2) 24 The volume is 24 units3. 20. The solid is a triangular prism. Its height is h 5 and its base has area B 1 2 (1)(1). V Bh 1 2 (1)(1)(5) 2.5 The volume is 2.5 units3. 21. The solid is a cylinder with r 2.1, h 3.5. V r2h (2.12)(3.5) 48.5 The volume is approximately 48.5 mm3.

Pages 692–694 Practice and Apply 7. The diameter of the base, the diagonal, and the lateral edge form a right triangle. Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 h2 92 ¬152 h2 81 ¬225 h2 ¬144 h ¬12 Now find the volume. V r2h (4.52)(12) 763.4 The volume is approximately 763.4 cm3. 8. V Bh (18.7)(12.2)(3.6) 821.3 The volume is approximately 821.3 in3. 9. Use the Pythagorean Theorem to find the height of the prism’s triangular base. Let b 1 2 (base of triangle) 3 cm a2 b2 ¬c2 a2 32 ¬82 a2 9 ¬64 a2 ¬55 a ¬ 55 Now find the volume of the prism. V Bh 1 )(12) 2 (6)(55

267.0 The volume is approximately 267.0 cm3. 10. The radius of the base is 1 2 (18) or 9. V r2h (92)(12.4) 3155.4 The volume is approximately 3155.4 m3. 11. V Bh (15)(10)(5) 750 The volume of the prism is 750 in3. 12. Find the area, B, of the base using the formula for the area of a trapezoid. B 1 2 h(b1 b2) 1 2 (4)(6 10)

32 Now find the volume of the prism. V Bh (32)(18) 576 The volume of the prism is 576 in3.

449

Chapter 13

26. The core radius is 1 2 (35) or 17.5. The core height is 586 40 or 626. V r2h (17.52)(626) 602,282.6 The volume is approximately 602,282.6 ft3. 27. The volume in gallons equals the volume r2h in cubic feet multiplied by a conversion factor of

22. Treat the solid as a large rectangular prism with a smaller one attached underneath. 22 cm B1 16 cm

h1 16 cm

8 cm

3 7 1 2 gal/ft .

h2 6 cm

B2

V r2h71 2

8 cm

200,000 r2h(7.5) Solve for r. 26,667 ¬ r2h 26,667 ¬ r2(23) r2 ¬369.1 r ¬19.2 The radius is approximately 19.2 ft. 28. Consider the water to be added as a rectangular prism, with a height of 3 0.3 or 2.7. V Bh (50)(25)(2.7) 3375 m3 Since 1 cubic meter equals 1000 liters, the volume of water to be added is 3375(1000) or 3,375,000 L. 29. Begin by finding the area of the hexagon.

volume volume of large rectangular prism volume of smaller rectangular prism B1h1 B2h2 (22)(8)(16) (8)(6)(6) 3104 The volume of the solid is 3104 cm3. 23. volume volume of rectangular prism volume of cylinder Bh r2h (6)(6)(6) (1.52)(6) 173.6 The volume is approximately 173.6 ft3. 24. The solid covers 360° 120° 240° of the 360° in 24 0 a cylinder. So the solid is 360 of a cylinder. 24 0 volume 360 volume of cylinder 2 2 3 r h

20

2 2 3 (4 )(10) 335.1 The volume is approximately 335.1 ft3. 25. The holder can be modeled as a cylindrical solid with a smaller cylindrical solid cut out of it. The smaller solid has the same radius as a can, and its height is 11.5 1 10.5. The larger solid has a radius of 1 2 (8.5) or 4.25.

r2

10 30

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The hypotenuse is 1 2 (20) or 10. So the shorter leg (10) 5 and the longer leg is 53 is 1 . This is the 2 length of the apothem. One side of the hexagon measures 10 mm, so the perimeter is 10 6 or 60. volume of brass block volume of rectangular prism volume of hexagonal prism B1h1 B2h2

6.5 cm

h2 10.5 cm

h1 11.5 cm

r1

wh1 1 2 Pah2

(50)(40)(60) 1 )(60) 2 (60)(53 104,411.5 The volume is approximately 104,411.5 mm3. 30. Set the density equal to mass volume, then use 8.0 g/cm3 as the density. For the volume, use 104,411.5 mm3 104.4115 cm3 from Exercise 29. d ¬m V

8.5 cm

volume volume of holder and “cut out” volume of “cut out” r12h1 r22h2 (4.25)2(11.5) (3.25)2(10.5) 304.1 The volume is approximately 304.1 cm3.

Chapter 13

m 8.0 ¬ 104.4115

m ¬(8.0)(104.4115) ¬835.3 The mass is approximately 835.3 g.

450

38. T 4 r2 4 (8.5)2 907.9 The surface area is approximately 907.9 in2. 39. T r r2 (6)(11) (62) 320.4 The surface area is approximately 320.4 m2. 40. radius 1 2 (16) 8 T r r2 (8)(13.5) (82) 540.4 The surface area is approximately 540.4 cm2. 41. Use the Pythagorean Theorem to find the slant height.

31. Start by finding the area of the base.

C 72

A

4

D

B

Apothem: The central angles of the pentagon are 36 0 all congruent, so mACB D is an 5 or 72. C apothem of the pentagon. It bisects ACB and is a perpendicular bisector of A B . So, mACD 36. 20 Since the perimeter is 20, AB 5 4 and 1 AD 2(4) 2. 2 tan 36° ¬ CD

2 CD ¬ tan 36°

¬2.7528

h 12

Area: A 1 2 Pa 1 2 (20)(2.7528)

r5 2

52 122 2 169 13 Now find the surface area of the cone. T r r2 (5)(13) (52) 282.7 The surface area is approximately 282.7 in2. 42. radius 1 2 (14) 7 Use the Pythagorean Theorem to find the slant height.

Now find the volume of the prism. V ¬Bh ¬1 2 (20)(2.7528)(5) ¬137.6 The volume is approximately 137.6 ft3. 32. Sample answer: Cartoonists use mathematical concepts or terms in comics because of the difficulty that many people have had with math. Answers should include the following. • A volume means a book. • In mathematics, volume refers to the amount of space that a figure encloses. 33. A; use the formula for the volume of a rectangular prism. V ¬Bh 16,320 ¬(85)w(8) 16,320 ¬680w w ¬24 ft 34. B; r2h 2 rh rh(r) rh(2) rh(r 2)

h 24

r7 2 72 242 2 625 25 Now find the surface area of the cone. T r r2 (7)(25) (72) 703.7 The surface area is approximately 703.7 in2. 43. Treat the floor plan as a large rectangle of width 12 9 21 and length 13 8 7 28, plus a 9 9 square. total area area of large rectangle area of square w s2 (28)(21) (9)2 669 shaded area 1w1 2w2 s2


35. radius 1 2 (12) 6 T 4 r2 4 (62) 452.4 The surface area is approximately 452.4 ft2. 36. T 4 r2 4 (412) 21,124.1 The surface area is approximately 21,124.1 cm2. 37. radius 1 2 (18) 9 2 T 4 r 4 (92) 1017.9 The surface area is approximately 1017.9 m2.

(9)(13) (12)(7) (9)2 282

451

Chapter 13

shaded area P(shaded) total area

48. Use Theorem 10.17, about a tangent segment and a secant segment. x2 12(12 9.5) x2 258 x 258 or 258 Since x is a length, it must be positive. So discard 258. x 16.1 49. Drawing the height divides the triangle into two 30°-60°-90° triangles each with base 1 2 (7) or 3.5. The height is then 3.5 3. For the whole equilateral triangle, A 1 2 bh

28 2 669

0.42 The probability is about 0.42, or 42%. 44.

30 26

13

1 ) 2 (7)(3.53 21.22 The area is approximately 21.22 in2.

15 6 The length of one side is 6 or 26. Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The shorter leg of the triangle is 1 2 (26) or 13. The apothem is the longer leg of the triangle or 133 .

50.

Area: A 1 2 Pa 1 ) 2 (156)(133

30

1756.3 The area is approximately 1756.3 in2.

12

6

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The shorter leg of the triangle is 21(12) or 6. The apothem is the longer leg of the triangle or 6 3. perimeter 12 6 72 Area: A 1 2 Pa

45. perimeter (6.2)(8) 49.6 A 1 2 Pa 1 2 (49.6)(7.5)

186 The area of the octagon is 186 m2. 46. Use Theorem 10.17 about a tangent segment and a secant segment. 132 ¬x(x 8) 169 ¬x2 8x 0 ¬x2 8x 169 Use the Quadratic Formula.

1 ) 2 (72)(63

374.12 The area is approximately 374.12 cm2. 51.

b b 4 ac x 2a 2

C

8 82 4(1)(1 69) 2(1)

72

6

8 740 or 8 740 2 2

Since x is a length, it must be positive. So discard

A

8 740 . 2

x 9.6 47. Use Theorem 10.16 about 2 secant segments. 8(8 6) ¬x(x 4) 112 ¬x2 4x 0 ¬x2 4x 112 Use the Quadratic Formula. b b 4 ac x 2 a 2

B

3 CD ¬ tan 36°

¬4.129 perimeter 5 6 30 Area: A 1 2 Pa

4 4 4(1)(1 12) 2(1) 2

429 429 4 or 4 2 2

1 2 (30)(4.129)

Since x is a length, it must be positive. So discard 429 4 . 2

61.94 The area is approximately 61.94 m2.

x 8.8 Chapter 13

D

Apothem: The central angles of the pentagon are 36 0 all congruent, so mACB D is an 5 or 72. C apothem of the pentagon. It bisects ACB and is a perpendicular bisector of A B . So, mACD 36. Since the side of the pentagon has measure 6, AD 3. 3 tan 36° ¬ CD

452

52.

3. The heights are the same. 4. V 1 3 Bh C

Pages 698–699 Check for Understanding 1. Consider first the base of the cone or pyramid. When a circle with area r2 is doubled in size, the new area is (2r)2 4( r2), or 4 times the original area. Similarly, when a square with area s2 is doubled in size, the new area is (2s)2 4s2, or 4 times the original area. When, for a cone or pyramid, the height is also doubled, the new volume is

45 50

A B D Apothem: The central angles of the octagon are 36 0 all congruent, so mACB D is an 8 or 45. C apothem of the octagon. It bisects ACB and is a perpendicular bisector of A B . So, mACD 22.5. Since the side of the octagon has measure 50, AD 25. 25 tan 22.5° ¬ CD

V 1 3 (4B)(2h) 81 3 Bh So in each case the volume is 8 times the original volume.

25 CD ¬ tan 22.5°

2. The volume of a pyramid is one-third the volume of a prism of the same height as the pyramid and with bases congruent to the bases of the pyramid. 3. Sample answer:

¬60.35534 perimeter 50 8 400 Area: A 1 2 Pa 1 2 (400)(60.35534)

12,071.07 The area is approximately 12,071.07 ft2.

16 9 3

4

Page 695 Spread Sheet Investigation: Prisms Use the formula A 2( w)h 2w in column E. Use the formula V wh in column F.

2 V 1 3 (3 )(16) V 48

Prism Length Width Height Surface Area Volume

1

1

02

03

0022

0006

2

2

04

06

0088

0048

3

3

06

09

0198

0162

4

4

08

12

0352

0384

5

8

16

24

1408

3072

2 V 1 3 (4 )(9) V 48

4. V 1 3 Bh 1 3 (16)(10)(12)

640 The volume of the pyramid is 640 in3. 5. Use the 30°-60°-90° triangle to find the radius of the base. The height of the cone is the longer leg and the radius of the cone is the shorter leg.

1. For each pair of prisms, the dimensions of the second prism are two times the dimensions of the first prism. 2. The surface areas of prisms 2, 4, and 5 are four times the respective surface areas of prisms 1, 2, and 4. 3. The volumes of prisms 2, 4, and 5 are eight times the respective volumes of prisms 1, 2, and 4. 4. When the dimensions are doubled, the surface area is multiplied by 4, or 22, and the volume is multiplied by 8, or 23.

1

r 12 43

3

2 V 1 3 r h 1 )2(12) 3 (43

603.2 The volume is approximately 603.2 mm3. 6. V 1 3 Bh 2 1 3 r h 2 1 3 (8 )(20)

1340.4 The volume is approximately 1340.4 ft3. 7. Use the formula for the volume of a cone.

13-2 Volumes of Pyramids and Cones

V 1 3 Bh

Page 696 Geometry Activity: Investigating the Volume of a Pyramid

1 3 (38,000)(77)

1. It took 3 pyramids of rice. 2. The areas of the bases are the same.

975,333.3 The volume is approximately 975,333.3 ft3.

453

Chapter 13

Pages 699–701

a2 b2 c2 7.52 h2 (103 )2 2 56.25 h ¬300 h2 ¬243.75 h ¬15.612 For the pyramid,

Practice and Apply

8. Find the area of the base first.

C

V 1 3 Bh

72

1 3 (20)(15)(15.612)

6

1561.2 The volume of the pyramid is approximately 1561.2 ft3. 10. Use the Pythagorean Theorem with h pyramid height. a2 b2 c2 92 h2 152 81 h2 ¬225 h2 ¬144 h ¬12 For the pyramid,

A D B Apothem: The central angles of the pentagon are 36 0 D is an all congruent, so mACB 5 or 72. C apothem of the pentagon. It bisects ACB and is a perpendicular bisector of A B . So, mACD 36. Since the side of the pentagon has measure 6, AD 3. 3 tan36° ¬ CD 3 CD ¬ tan 36°

V 1 3 Bh

¬4.13 perimeter 5(6) 30 cm

1 3 (24)(18)(12)

1728 The volume of the pyramid is 1728 in3. 11. Use the Pythagorean Theorem with h cone height. a2 b2 c2 182 h2 302 324 h2 ¬900 h2 ¬576 h ¬24 For the cone,

Base area: A ¬1 2 Pa ¬1 2 (30)(4.13)

¬61.95 Now find the volume of the pyramid. V ¬1 3 Bh ¬1 3 (61.95)(10)

¬206.5 The volume of the pyramid is approximately 206.5 cm3. 9. Find the height of the pyramid by first finding the height of one of the 20-20-20 triangular faces (a pyramid slant height).

2 V 1 3 r h 2 1 3 (18 )(24)

8143.0 The volume is approximately 8143.0 mm3. 12. Use the 45°-45°-90° triangle to find the radius of the base: r 1 10 5 2. In the same way, find 2

. For the pyramid, the height: h 1 10 52

30 20

20

2

2 V 1 3 r h

1 )2(52 ) 3 (52

10

370.2 The volume is approximately 370.2 in3

10

13.

The height of this triangle is 103 . Now use the Pythagorean Theorem with h pyramid height. The distance from the center of the base of the pyramid to one of the 20-in. edges is 1 2 (15) or 7.5.

r h A 30 36

h

10 3

7.5

Chapter 13

454

15. Use the Pythagorean Theorem with d diameter of base. a2 b2 c2 d2 52 132 d2 25 ¬169 d2 ¬144 d ¬12 For the cone, the radius is 21(12) or 6. The volume is

Use trigonometry to find the radius of the base. 1(36°) 18° 2 opposite sin A ¬ hypotenuse r sin18° ¬ 30

r ¬30sin18° r ¬9.2705 Similarly, find the height.

V 1 3 Bh

adjacent

cosA ¬ hypotenuse

2 1 3 r h

h cos 18° 30

2 1 3 (6 )(5)

h ¬30 cos 18° h ¬28.5317 Now find the volume.

188.5 The volume is approximately 188.5 cm3. 16. The radius of the base is r 1 2 (24) 12. Use the 30°-60°-90° triangle to find the height, which is the shorter leg: h 1 2 (15) 7.5. For the cone,

2 V 1 3 r h 2 1 3 (9.2705) (28.5317)

2567.8 The volume of the cone is approximately 2567.8 m3. 14. Calculate the area of the base, B, first.

2 V 1 3 r h 2 1 3 (12 )(7.5)

1131.0 The volume is approximately 1131.0 ft3. 17. Find the height of the pyramid portion by first finding the height of one of the triangular sides (the pyramid slant height). Use the Pythagorean Theorem.

15

15

h1

8

10

4

10

h1

1(8) 4. Now use the Pythagorean Theorem to 2

find the height of the triangular base. a2 b2 c2 42 h12 152 16 h12 ¬225 h12 ¬209 h1 ¬209

12

6

62 h12 102 36 h12 ¬100 h12 ¬64 h1 ¬8 Now find the height of the pyramid, again using the Pythagorean Theorem. a2

Now calculate the area of the base. B 1 2 bh1 1 ) 2 (8)(209

4209 Now find the height of the pyramid. a2 b2 c2 152 h22 172

b2

c2

8

8

h2

225 h22 ¬289 h22 ¬64 h2 ¬8 For the pyramid,

12

6

V 1 3 Bh2 1 )(8) 3 (4209

154.2 The volume is approximately 154.2 m3.

455

Chapter 13

a2 b2 c2 62 h22 82 36 h22 ¬64 h22 ¬28 h2 ¬27 volume of solid volume of cube volume of pyramid s3 1 3 Bh2

a2 b2 ¬c2 (24 16)2 h2 ¬102 64 h2 ¬100 h2 ¬36 h ¬6 cm Let x equal the height of the “missing” cone. By using similar triangles, 16 x 24 ¬ x 6 2 ¬x x6 3

123 1 ) 3 (12)(12)(27

2(x 6) ¬3x 2x 12 ¬3x x ¬12 cm

1982.0 The volume is approximately 1982.0 mm3. 18. Calculate the area of the hexagon first. The center-to-vertex distance, s, which in a regular hexagon equals the side length, is found using the Pythagorean Theorem.

volume of frustum ¬volume of large cone volume of “missing” cone 2 1 2 ¬1 3 r (x h) 3 r x 2 2 1 ¬1 3 (24 )(12 6) 3 (16 )(12)

9.3

¬7640.4 cm3 20. r 1 2 (103) 51.5 km, h 4.17 km

10

2 V 1 3 r h

2 1 3 (51.5 )(4.17)

11,581.9 The volume is approximately 11,581.9 km3.

s 2 2 a b ¬c2 s2 9.32 ¬102 s2 86.49 ¬100 s2 ¬13.51 s ¬13.51 Apothem:

21.

m 3.776 k

9

Use trigonometry to find the radius of the base. 3.7 76 tan 9° ¬ r 3.7 76 r ¬ tan 9°

¬23.840726 2 V 1 3 r h 2 ¬1 3 (23.840726 )(3.776)

2247.5 The volume is approximately 2247.5 km3.

30

1 2

22. 13.51 410

The apothem is 3 1213.51 .

33

perimeter 613.51

r Use trigonometry to find the radius of the base.

Area: A 1 2 Pa

41 0 tan 33° ¬ r

3 1 ) 2 13.51 2 (613.51

41 0 r ¬ tan 33°

35.1 volume of solid ¬2 volume of one pyramid

¬631.344635 2 V 1 3 r h

¬2 1 3 Bh

2 1 3 (631.344635 )(410)

¬2 1 3 (35.1)(9.3)

171,137,610.4 The volume is approximately 171,137,610 m3.

¬217.6 ft3 19. Use the Pythagorean Theorem to find the height of the frustum. 16 mm 10 24 mm

Chapter 13

24 16 mm

456

23. r 1 2 (22.3) 11.15

30. Side view of tower with “missing portion”:

2 V 1 3 r h 2 1 3 (11.15 )(1.22)

158.8 The volume is approximately 158.8 km3. 24. 2 3 ; The volume of each pyramid that makes up the solid on the left is 1 3 of the volume of the prism, so 1 the total volume of the solid on the left is 1 3 3 or 2 3 of the volume of the prism. 25. Use the formula for the volume of a pyramid.

h

8

V 1 3 Bh 2 1 3 (755 )(481)

35

91,394,008.3 The original volume of the pyramid is approximately 91,394,008.3 ft3. 26. Use the formula for the volume of a pyramid.

15

V 1 3 Bh

By similar triangles, 8 h 1 5 h 35 8h 280 ¬15h 280 ¬7h h ¬40 ft volume of frustum ¬volume of large pyramid volume of “missing” portion

2 1 3 (755 )(449)

85,313,741.7 The present day volume of the pyramid is approximately 85,313,741.7 ft3. 27. 91,394,008.33 85,313,741.67 6,080,266.7 Approximately 6,080,266.7 cubic feet have been lost. 28. The volume of the cone is 1 3 of the volume of the cylinder, so probability 1 1 3 2 3 29. Find the height of the pyramid using the Pythagorean Theorem.

1 ¬1 3 B1h1 3 B2h2 2 1 2 ¬1 3 (15 )(35 40) 3 (8 )(40)

¬4771.7 The volume of the frustum is approximately 4771.7 ft3. 31. Calculate the slant height, using the fact that each face is an equilateral triangle.

A 30

12 8

8

h1 B

5

5

12

6

6

C

The slant height equals 63 because it is the measure of the longer leg of the 30°-60°-90° right triangle. Now find the apothem of the base.

a2 b2 c2 52 h12 82 25 h12 ¬64 h12 ¬39 h1 ¬ 39 For the cone, radius 1 2 (10) or 5. volume of solid ¬volume of oblique pyramid volume of cone 1 2 ¬1 3 Bh1 3 r h2

12

12

a 6

30 6

1 The apothem a equals 6 23 . Now find

2 ¬1 ) 13 (52)(12) 3 (10 )(39

3

the height of the solid, using the Pythagorean Theorem.

¬522.3 The volume of the solid is approximately 522.3 units3.

457

Chapter 13

36. V r2h (82)(17) 3418.1 The volume is approximately 3418.1 m3. 37. Use the Pythagorean Theorem to find the height of the triangle. One leg of the right triangle is 21(10) or 5 ft.

6 3

h

2 3

a2 b2 ¬c2 2 h (23 )2 ¬(63)2 2 h 12 ¬108 h2 ¬96 h ¬4 6 Find the area of the base, B.

13

B 1 2 Pa

10

363 For the pyramid, V ¬1 3 Bh ¬1 )(46) 3 (363

¬203.6 The volume is approximately 203.6 in3. 32. Sample answer: Architects use geometry to design buildings that meet the needs of their clients. Answers should include the following. • The surface area at the top of a pyramid is much smaller than the surface area of the base. There is less office space at the top, than on the first floor. • The silhouette of a pyramid-shaped building is smaller than the silhouette of a rectangular prism with the same height. If the light conditions are the same, the shadow cast by the pyramid is smaller than the shadow cast by the rectangular prism. 33. B; V 1 3 Bh

2

4 3 4

2354.2 The surface area is approximately 2354.2 cm2. 39. T 4 r2 4(64.5) 258 The surface area is 258 yd2. 40. For the “missing” triangular corner, base 335 190 145 height 325 220 105 area of field ¬area of large rectangle area of “missing” triangle ¬w 1 2 bh ¬(325)(335) 1 2 (145)(105) ¬101,262.5 The total area is 101,262.5 ft2. 41. 4 r2 4 (3.42) 145.27

2 1 3b h

2 1 3 (2h) h 3

4h 3

34. A; x3 9x x(x2 9) x(x2 9) or x(x2 9) x(x 3)(x 3) or x(x2 9) x(x2 9) is not one of the choices given. So the factors that could represent length, width, and height are x, x 3, and x 3.


3 3 4 42. 4 3 r 3 (7 )

35. V Bh (14)(12)(6) 1008 The volume of the prism is 1008 in3.

Chapter 13

5

a2 b2 ¬c2 h2 52 ¬132 h2 25 ¬169 h2 ¬144 h ¬12 For the prism, taking the triangles as bases, V ¬Bh ¬1 2 (10)(12)(19) ¬1140 The volume of the prism is 1140 ft3. 38. Use the circumference to find the radius. C ¬2 r 86 ¬2 r 43 ¬r Now find the area. T 4 r2

1 ) 2 (36)(23

Page 701

13

h

1436.76 43. 4 r2 4 (122) 1809.56

458

Page 701

5. Use the Pythagorean Theorem to find the height of the triangular base.

Practice Quiz 1

1. Use the formula for the volume of a cylinder. The radius is r 1 2 (4) or 2. V r2h (22)(10) 125.7 The volume is approximately 125.7 in3. 2. Use the formula for the volume of a cylinder. The radius is r 1 2 (12) or 6. V r2h (62)(15) 1696.5 The volume is approximately 1696.5 m3. 3. First find the area of the hexagonal base.

11

11

6 3

a2 b2 ¬c2 32 h2 ¬112 9 h2 ¬121 h2 ¬112 h ¬4 7 Now find the area of the base, B. B ¬1 2 bh

30 6

¬1 ) 2 (6)(47

3

¬127

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The shorter leg of the triangle is 1 2 (6) or 3. The apothem is the longer leg of the triangle or 33 . perimeter 6 6 36 The area of the hexagonal base is

For the pyramid, V ¬1 3 Bh ¬1 )(4) 3 (127

¬42.3 The volume is approximately 42.3 in3.

A 1 2 Pa 1 ) 2 (36)(33

543 For the prism, V Bh (54 3)(10) 935.3 The volume is approximately 935.3 cm3. 4.

13-3 Volumes of Spheres Page 704 Check for Understanding 1. The volume of a sphere was generated by adding the volumes of an infinite number of small pyramids. Each pyramid has its base on the surface of the sphere and its height from the base to the center of the sphere. 2. Kenji; Winona divided the 12 by 3 before raising the result to the third power. Thus the order of operations was not followed correctly.

r

h 30

20

3 3. V ¬4 3 r 3 ¬4 3 (13 )


Use a 30°-60°-90° triangle to find the radius of the base and the height.

4. The radius is 1 2 (12.5) 6.25. 4 V ¬3 r3

r 1 ft. 2 (20) or 10 ft, and h 103

For the cone,

3 ¬4 3 (6.25 )

2 V ¬1 3 r h

¬1022.7 The volume is approximately 1022.7 cm3.

2 ¬1 ) 3 (10 )(103

¬1813.8 The volume is approximately 1813.8 ft3.

459

Chapter 13

3 5. V ¬4 3 r

13. Use the circumference to find the radius. C ¬2 r 24 ¬2 r 12 ¬r Now find the volume.

3 ¬4 3 (4 )

¬268.1 The volume is approximately 268.1 in3. 6. Use the circumference to find the radius. C ¬2 r 18 ¬2 r 9 ¬r π 3 V ¬4 3 r 9 ¬4 3 π

3 V ¬4 3 r

¬233.4 The volume is approximately 233.4 in3. 3 14. V ¬4 3 r

3

3 ¬4 3 (35.8 )


¬192,193.1 The volume is approximately 192,193.1 mm3.

7. The radius is 1 2 (8.4) 4.2. 1 4 3 V ¬2 3 r 3 ¬2 3 (4.2 )

3 ¬2 3 (3.2 )

¬68.6 The volume is approximately 68.6 m3.

¬155.2 The volume is approximately 155.2 m3. 8. For the sphere,

16. radius 1 2 (28) 14 1 4 V ¬2 3 r3

3 V ¬4 3 r

3 ¬4 3 (5 )

¬5747.0 The volume is approximately 5747.0 ft3. 3 17. V ¬4 3 r

2 V ¬1 3 r h

3 ¬4 3 (12 )

2 ¬1 3 (5 )(20)

¬7238.2 The volume is approximately 7238.2 in3. 18. Find the radius. C ¬2 r 48 ¬2 r

50 0 ¬ 3 The two volumes are equal.

Pages 704–706 Practice and Apply 3 9. V ¬4 3 r

24 ¬r

3 ¬4 3 (7.62 )

Now find the volume.


3 V ¬4 3 r

¬1867.6 The volume is approximately 1867.6 cm3. 19. Use the formula for the volume of a sphere.

3 ¬4 3 (16.5 )

¬18,816.6 The volume is approximately 18,816.6 in3.

radius 1 2 (3476) 1738 3 V ¬4 3 r

11. radius 1 2 (18.4) 9.2 4 3 V ¬3 r

3 ¬4 3 (1738 )

¬21,990,642,871 The volume is approximately 21,990,642,871 km3.

3 ¬4 3 (9.2 )

¬3261.8 The volume is approximately 3261.8 ft3.

2

20. For the golf ball, r 1 2 (4.3) 2.15. 3 V ¬4 3 r

3 ¬4 3 (2.15 )

3

¬41.63


Chapter 13

3

24 ¬4 3

10. radius 1 2 (33) 16.5 4 3 V ¬3 r

3

3 ¬2 3 (14 )

50 0 ¬ 3 For the cone,

3 12. V ¬4 3 r 3 ¬4

4 3 15. V ¬1 2 3 r

3

12 ¬4 3

460

For the tennis ball, r 1 2 (6.9) 3.45.

28. For the cylinder, r 1 2 (2.5) 1.25. V r2h (1.252)(7.5) 36.82 For the three balls, r 1 2 (2.5) 1.25.

3 V ¬4 3 r

3 ¬4 3 (3.45 )

¬172.01 The difference is about 172.01 41.63 or 130.4 cm3.

3 V ¬3 4 3 r

¬4 (1.253) ¬24.54 volume of empty space 36.82 24.54 12.3 in3 29. For the cube, V ¬s3 216 ¬s3 6 ¬s

21. For the cone, r 1 2 (4) 2. 2 V ¬1 3 r h 2 ¬1 3 (2 )(10)

¬41.9 cm3 For the ice cream, r 1 2 (4) 2. 3 V ¬4 3 r 3 ¬4 3 (2 )

¬33.5 cm3 Since the volume of the ice cream is less than the volume of the cone, the cone will not overflow.

r

3 3 2

33 .5 volume of ice cream 22. volume of cone 41.9

3

0.80 The cone will be about 80% filled.

3

3 23. V ¬4 3 r 3 ¬4 3 (17 )

24.

25.

26.

27.

¬20,579.5 The volume is approximately 20,579.5 mm3. total volume “just right” percentage 20,579.5 0.59 12,141.9 The “just right” volume is approximately 12,141.9 mm3. T 4 r2 4 (172) 3631.68 total area “wish for more” percentage 3631.7 0.32 1162.1 The “wish for more” surface area is approximately 1162.1 mm2. A r2 (172) 907.9 mm2 total area “wish for less” percentage 907.9 0.09 81.7 The area of the “wish for less” sector is approximately 81.7 mm2. For the sphere,

The radius of the sphere appears as r in the figure. It is found by two applications of the Pythagorean Theorem. First, for the horizontal right triangle: a2 b2 ¬c2 32 32 ¬c2 18 ¬c2 18 ¬c 32 ¬c Now for the vertical right triangle: a2 b2 ¬c2 (32)2 32 ¬r2 27 ¬r2 27 ¬r 33 ¬r For the sphere, 3 V ¬4 3 r ¬4 )3 3 (33

¬587.7 The volume of the sphere is approximately 587.7 in3. 30. Find the radius. T ¬4 r2 784 ¬4 r2 196 ¬r2 14 ¬r Now find the volume.

3 V ¬4 3 r 3 ¬4 3 (6 )

¬288 cm3 For the cylinder, V r2h (62)(12) 432

3 V ¬4 3 r 3 ¬4 3 (14 )

¬11,494.0 The surface area is approximately 11,494.0 in3.

volume of sphere 288 2 432 3 volume of cylinder

461

Chapter 13

31. total area area of curved half-sphere area of flat bottom

40. Use the formula for the volume of a rectangular prism. V ¬Bh 25.9 ¬(2.4)(5.0) 25.9 ¬12 2.2 ¬ The depth is approximately 2.2 ft. 41. (x h)2 (y k)2 ¬r2 (x 2)2 [y (1)]2 ¬82 (x 2)2 (y 1)2 ¬64

2 2 T 1 2 (4 r ) r

Find the radius. 18.75 ¬3 r2 6.25 ¬r2 2.5 ¬r Now find the volume.

4 3 V ¬1 2 3 r

42.

3 ¬2 3 (2.5 )


43. Find the center of the circle.

volume volume of cylinder volume of hemisphere

y y

5 (1)

(2, 1) Find the radius.

4 3 r2h 1 2 3 r

1 diameter 1 5]2 [6 (4)] 2 2 2 [1

3 (712)(71) 2 3 (71 )

34 (x h)2 (y k)2 ¬r2 2 (x 2)2 (y 1)2 ¬(34 ) 2 2 (x 2) (y 1) ¬34

1,874,017.6 The volume is approximately 1,874,017.6 ft3. 33. radius 1 2 (4) 2

volume volume of cylinder combined volume of 2 hemispheres

44. (2a)2 (2a)(2a) 22aa 4a2 3 45. (3x) (3x)(3x)(3x) 333xxx 27x3

3 r2h 4 3 r

3 (22)(12) 4 3 (2 ) 184 The volume is approximately 184 mm3. 34. Sample answer: If a student knows the circumference of a sphere, then the volume can be found. Answers should include the following. • One needs to know the radius of the Earth. • The radius of Earth is about 6366.2 km and the volume is about 1.1 1012 km3. 35. See student’s work. 36. A; the ratio of the volumes is the cube of the 3 ratio of the radii, namely 3 5 0.216 or 21.6%.

2 5a 5a 5a 46. b b b 5a 5a bb

5 5 aa bb 2

a 25 2

b 3 2 k 2 2k 2k 47. 5 5k 5 5 2k 2k 2 k 5 5 5 2 2 2 kkk 555 3 8k 12 5

2 2 2 2 2 2 1 37. A; 1 2 (4 r ) r h 2 (4 r ) 2 r r h 2 r

r2(2 h 2) r2(4 h)

13-4 Congruent and Similar Solids

Page 706 Maintain Your Skills 2 38. V ¬1 3 r h

Page 709 Spreadsheet Investigation: Explore Similar Solids

2 ¬1 3 (6 )(9.5)


1. If a number in row 6 is a, then row 7 contains a2, and row 8 contains a3. 2. The ratio of the surface areas is a2 : b2. 3. The ratio of the volumes is a3 : b3.

39. radius 1 2 (15) 7.5 1 2 V ¬3 r h 2 ¬1 3 (7.5 )(7)


Chapter 13

x x

4 6 1 2 1 2 M 2, 2 2, 2

32. radius 1 2 (142) 71

(x h)2 (y k)2 ¬r2 2 [x (4)]2 [y (3)]2 ¬(19 ) (x 4)2 (y 3)2 ¬19

462

Page 710


1. Sample answer:

Pages 711–713

5 in.

7 in.

5 in.

7 in. 6 in. 12 in.

8 in.

2. If two solids are similar with a scale factor of a : b, then the surface areas have a ratio of a2 : b2 and the volumes have a ratio of a3 : b3. 3. The two cones are of exactly the same shape and size, so they are congruent. height of larger cylinder

30 4. 20 height of smaller cylinder 3 2 diameter of larger cylinder 22 .5 15 diameter of smaller cylinder 3 2

length of smaller prism

10 2 15. 15 3 length of larger prism

The two solids are similar. Since the scale factor is not 1, they are not congruent.

width of smaller prism 1 3 width of larger prism

height of larger pyramid 24 5. 18 height of smaller pyramid 4 3

Since the ratios are not the same, the pyramids are neither congruent nor similar. 16. The cubes are identical in shape but not in size, so they are similar (but not congruent).

The scale factor is 4 : 3. surface area of larger pyramid surface area of smaller pyramid

2

6. a2

b 2 42 3 16 9

17. 26 5 1 130 m high 49 5 1 245 m wide 93 5 1 465 m long

The ratio of the surface areas is 16 : 9. volume of larger pyramid volume of smaller pyramid

18. Always; spheres have only one measure to compare. 19. Always; congruent solids have equal dimensions. 20. Sometimes; if the solids have a scale factor of 1, the volumes will be equal. 21. Never; different solids cannot be similar. 22. Never; different solids cannot be similar. 23. Sometimes; solids that are not similar can have the same surface area.

3

7. a3

b 3 4 3 3 64 27

The ratio of the volumes is 64 : 27. diameter of smaller ball 2 8. diameter of larger ball 16 1 8 The scale factor is 1 : 8.

1 24. 15 1000 0.015

2 surface area of smaller ball a 9. surface area of larger ball b2

The Micro-Car door handle is 0.015 cm long.

2

12

1,000,000 10 00 2 25. x x 1 1

8 1 6 4

1,000,000x The full-sized car’s surface area is 1,000,000x cm2.

The ratio of the surface areas is 1 : 64. volume of smaller ball volume of larger ball

Practice and Apply

11. The bases have different shapes, so the two pyramids are neither congruent nor similar. 12. The spheres are identical in shape but not in size (unless a b), so they are considered similar. 13. Use the Pythagorean Theorem to find the height of the second cylinder. a2 b2 ¬c2 122 h2 ¬202 144 h2 ¬400 h2 ¬256 h ¬16 in. Since the two cylinders have the same height and diameter (2 6 12), they are congruent. base edge of larger pyramid 12 6 14. base edge of smaller pyramid 43 3 2 height of larger pyramid 3 6 6 height of smaller pyramid 122 3 3 Since the ratios are not the same, the pyramids are neither congruent nor similar.

7 in.

3

1 15 26. 15 18 18

10. a3

b 3 13 8 1 512

5 6 The miniature door handle would be 5 6 or about 0.83 cm long.

The ratio of the volumes is 1 : 512.

463

Chapter 13

perimeter of smaller prism perimeter of larger prism

volume of smaller ball volume of larger ball

height of smaller prism’s base height of larger prism’s base 4 10 2 5

surface area of smaller prism surface area of larger prism

length of gigantic ear of corn 38 4 10 length of real ear of corn 19 2 5

2

28. a2

The scale factor is 192 : 5. 37. Let V volume of normal kernel.

b 2 2 2 5 4 25

231 a3 3 V ¬b 3 19 ¬ 2 53 7,077,888 ¬ 12 5

The ratio of the surface areas is 4 : 25. 3

29. a3

b 3 23 5 8 125

28,875 ¬7,077,888V V ¬0.004 The volume of a normal kernel is approximately 0.004 in3.

The ratio of the volumes is 8 : 125. 30. Let V volume of larger prism. 8 48 V ¬ 125

5 38. scale factor 1 0 1 2

6000 ¬8V V ¬750 The volume of the larger prism is 750 in3.

3 volume of smaller cone a b3 volume of original cone 3 13 2 1 8

31. scale factor 5 6 Let V volume of larger cone.

Since the smaller cone has 1 8 the volume of the 7 original cone, the frustum has 1 1 8 8 the volume of the original cone.

125 a3 3 V ¬b 3 12 5 5 V ¬ 63 125 12 5 ¬ V 216

7 volume of frustum 7 8 1 8 or 7:8 volume of original cone

27,000 ¬125V V ¬216

volume of frustum volume of smaller cone

2 Since V ¬1 3 r h,

radius of upper circle 1 2 radius of lower circle 1 r radius of lower circle 2

18 ¬h The height of the larger cone is 18 cm. 32. 5 ft 5 12 60 in. diameter of normal pie 8 6 0 diameter of large pie 2 15

7 1 or 7:1

5 cm

radius of lower circle 2r The lateral area of the smaller cone is L r(5) 5 r. The lateral area of the larger cone is L (2r)(10) 20 r. lateral area of the frustum lateral area of the larger cone lateral area of the smaller cone 20 r 5 r 15 r

volume of normal pie a3 b3 volume of large pie 3 23 15 8 3375

The ratio of the volumes is 8 : 3375. diameter of smaller ball

29 33. 30 diameter of larger ball The scale factor is 29 : 30.

10 cm

r

2r

lateral area of frustum 15 r 3 20 r 4 or 3 : 4 lateral area of original cone lateral area of frustum r 15 3 5 r 1 or 3 : 1 lateral area of smaller cone

2

34. a2

b 2 29 302 84 1 900

40. Yes, both cones have congruent radii. If the heights are the same measure, the cones are congruent.

The ratio of the surface areas is 841 : 900.

Chapter 13

7 8 1 8

39. Let r the radius of the upper circle. Since the 5 1 scale factor 1 0 or 2,

2 216 ¬1 3 (6 )h

surface area of smaller ball surface area of larger ball

30 24,389 27,0 00

The ratio of the volumes is 24,389 : 27,000. 36. 32 ft 32 12 384 in.

The ratio of the perimeters of the bases is 2 : 5.

volume of smaller prism volume of larger prism

3

29 35. 3

27.

464

41. The volume of the cone on top is equal to the sum of the volumes of the cones inside the cylinder. Justification: Call h the height of both solids. The 2 volume of the cone on top is 1 3 r h. If the height of one cone inside the cylinder is c, then the height of the other one is h c. Therefore, the

49.

A

46

Use trigonometry to find the radius of the base. 1(46°) ¬23° 2 opposite sinA ¬ hypotenuse r sin23° ¬ 13

• The actual object is 108 in. long. 2

small area a 43. C; large area ¬ b2 ¬4 9

r ¬13sin23° ¬5.0795 Similarly, find the height.

2 ¬22 3 scale factor 2 3 3 s m a l l v o l u m e a large volume b3 3 23 3 8 or 8 : 27 27

adjacent

cosA ¬ hypote nuse h cos23° ¬ 1 3

h ¬13cos23° ¬11.967 Now find the volume.

xyz

44. D; xy xy y z y2z

2 V ¬1 3 r h

4 5 or 0.8

Page 713

13

h

2 sum of the volume of the two cones is: 1 3 r c 1 1 1 r2(h c) or r2(c h c) or r2h. 3 3 3 42. Sample answer: Scale factors relate the actual object to the miniatures. Answers should include the following. • The scale factors that are commonly used are 1 : 24, 1 : 32, 1 : 43, and 1 : 64.

yz

r

2 ¬1 3 (5.0795) (11.967)



45. radius 1 2 (8) 4 4 3 V 3 r

50. V 1 3 Bh 1 3 (11)(7)(15)

3 4 3 (4 )

385 The volume of the pyramid is 385 m3. 51. Use trigonometry to find the radius of the base.

268.1 The volume is approximately 268.1 ft3.

opposite adjacent 21 tan62° ¬ r 21 r ¬ tan 62°

3 46. V 4 3 r

tanA ¬

3 4 3 (9.5 )

3591.4 The volume is approximately 3591.4 m3.

¬11.166 Now find the volume. 2 V ¬1 3 r h

3 47. V 4 3 r 3 4 3 (15.1 )

14,421.8 The volume is approximately 14,421.8 cm3.

2 ¬1 3 (11.166) (21)

¬2741.8 The volume is approximately 2741.8 ft3. 52. Start with the formula for the surface area of a cylinder. T ¬2 rh 2 r2 430 ¬2 r(7.4) 2 r2 Solve for r. 2 r2 14.8 r 430 0

48. radius 1 2 (23) 11.5 4 3 V 3 r 3 4 3 (11.5 )

6370.6 The volume is approximately 6370.6 in3.

465

Chapter 13

57. y 3x 5 Use x 4, y 17. 17 3(4) 5 17 12 5 17 17 Yes, the ordered pair is on the graph. 58. y 4x 1 Use x 2, y 9. 9 4(2) 1 981 99 Yes, the ordered pair is on the graph. 59. y 7x 4 Use x 1, y 3. 3 7(1) 4 3 7 4 3 11 No, the ordered pair is not on the graph.

Use the Quadratic Formula. 2 4ac b b r ¬ 2a

14.8 (14.8 )2 4(2 )( 430) ¬ 2(2 )

¬5.4 or 12.8 Since the radius cannot be negative, discard 12.8. The radius is approximately 5.4 cm. 53. Start with the formula for the surface area of a cylinder. T ¬2 rh 2 r2 224.7 ¬2 r(10) 2 r2 Solve for r. 2 r2 20 r 224.7 0 Use the Quadratic Formula. 2 4ac b b r ¬ 2a 20 (20 )2 4(2 )(2 24.7) ¬ 2(2 )

¬2.8 or 12.8 Since the radius cannot be negative, discard 12.8. The radius is approximately 2.8 yd. 54. Use the Pythagorean Theorem to find the height of the triangle.

Page 713

Practice Quiz 2

3 1. V ¬4 3 r 3 ¬4 3 (25.3)

¬67,834.4 The volume is approximately 67,834.4 ft3. 2. radius 1 2 (36.8) 18.4 4 V 3 r3

100

3 4 3 (18.4)

100

26,094.1 The volume is approximately 26,094.1 cm3. base side of left pyramid

3. 7 5 base side of right pyramid

The scale factor is 7 : 5.

70

surface area of left pyramid surface area of right pyramid

a2 b2 ¬c2 352 h2 ¬1002 1225 h2 ¬10,000 h2 ¬8775 h ¬15 39 For the triangle,

b 2 7 2 5 49 25

The ratio of the surface areas is 49 : 25. volume of left pyramid volume of right pyramid

3

5. a3

A ¬1 2 bh ¬1 ) 2 (70)(1539

¬3279 The area is approximately 3279 yd2. 55. Use the formula for the area of a rectangle. A w (12)(3) 36 The area of the rowboat is 36 ft2. 56. 3279 yd2 3279 9 29,511 ft2

b 3 73 5 34 3 125

The ratio of the volumes is 343 : 125.

13-5 Coordinates in Space Page 717


1. The coordinate plane has 4 regions or quadrants with 4 possible combinations of signs for the ordered pairs. Three-dimensional space is the intersection of 3 planes that create 8 regions with 8 possible combinations of signs for the ordered triples.

area of ro wboat probability ¬ shaded area 36 ¬ 29,5 11

¬0.0012

Chapter 13

2

4. a2

35

466

2. Sample answer: Use the point at (2, 3, 4); A(2, 3, 4), B(2, 0, 4), C(0, 0, 4), D(0, 3, 4), E(2, 3, 0), F(2, 0, 0), G(0, 0, 0), and H(0, 3, 0).

8. First, write a vertex matrix. M

N

Q

R

S

0 4 0

0 0 2

0 3 3 4 4 0 2 2 2

z

D (0, 3, 4)

C (0, 0, 4)

P

x 0 3 3 y 0 0 4 z 0 0 0

T

V

Next, multiply each element by the scale factor, 2. B (2, 0, 4)

M

A (2, 3, 4) G (0, 0, 0)

y

F (2, 0, 0)

Q

R

S

0 4 0

0 0 2

0 3 3 4 4 0 2 2 2

P

Q

R

S

0 6 6 0 0 8 0 0 0

0 8 0

0 0 4

0 6 6 8 8 0 4 4 4

M

E (2, 3, 0)

x

N

H (0, 3, 0) O

P

0 3 3 2 0 0 4 0 0 0 N

3. A dilation of a rectangular prism will provide a similar figure, but not a congruent one unless r 1 or r 1. 4. z C (0, 0, 5) D (0, 1, 5)

z

A (2, 1, 5)

V

G (0, 0, 0) 4

F (2, 0, 0)

y

T

V

T

N R

4

O

4

P

S

M

E (2, 1, 0)

x

V

The coordinates of the vertices of the dilated image are M (0, 0, 0), N (6, 0, 0), P (6, 8, 0), Q (0, 8, 0), R (0, 0, 4), S (0, 8, 4), T (6, 8, 4), and V (6, 0, 4).

B (2, 0, 5)

O H (0, 1, 0)

T

Q

y

x

5.

z

9. Write the coordinates of each corner. Then use the translation equation (x, y, z) → (x 48, y, z 16) to find the coordinates of each vertex of the rectangular prism that represents the storage container.

Q ( 1, 0, 2) P ( 1, 4, 2) R (0, 0, 2)

S (0, 4, 2) T ( 1, 4, 0)

U ( 1, 0, 0) V (0, 0, 0) O

W (0, 4, 0)

Coordinates of the Translated coordinates, vertices, (x, y, z) (x 48, y, z 16) Preimage Image

y

x 2 2 2 (x2 x 6. DE 1) (y 2 y 1) (z 2 z 1)

(12, 8, 8)

(36, 8, 24)

(1 0 )2 (5 0)2 (7 0)2

(12, 0, 8)

(36, 0, 24)

75 or 53

(0, 0, 8)

(48, 0, 24)

x x

y y

z z

1 5 7 0 0 0 2, 2, 2 5 7 1 2, 2, 2

1 2 1 2 1 2 M 2, 2, 2

7. GH (x2 x1)2 (y2 y1)2 (z2 z1)2

(0, 8, 8)

(48, 8, 24)

(12, 8, 0)

(36, 8, 16)

(12, 0, 0)

(36, 0, 16)

(0, 0, 0)

(48, 0, 16)

(0, 8, 0)

(48, 8, 16)

2 [5 ( 3)]2 [3 (4)] (5 6)2

186 x x

y y

Pages 717–719

z z

5 3 5 4 3 6 2, 2, 2 1 1, 7 2, 2

10.

1 2 1 2 1 2 M 2, 2, 2

Practice and Apply z

F ( 2, 0, 2) C ( 2, 2, 2) D (0, 2, 2) G ( 2, 2, 0)

H ( 2, 0, 0) E (0, 0, 2) I (0, 0, 0) O

J (0, 2, 0)

y

x

467

Chapter 13

11.

x1)2 (y2 y1)2 (z2 z1)2 16. KL (x 2

z

T (0, 0, 1)

S (0, 4, 1) W (0, 4, 0)

(2 2)2 (2 2)2 (0 0)2

O

32 or 42

A (0, 0, 0) y

R (3, 4, 1)

x x

V (3, 4, 0)

B (3, 0, 0) x

12.

17. PQ (x2 x1)2 (y2 y1)2 (z2 z1)2 2 2 ( [3 (2)] [2 (5)] 1 8)2

D (0, 6, 0)

O

y

A (0, 0, 0)

115

E (0, 0, 3)

x x

G (0, 6, 3)

x

F (4, 0, 3)

P (4, 6, 3)

2

x x

I (0, 0, 3)

3 5

0

0

19. GH (x x1)2 (y2 y1)2 (z2 z1)2 2

G (4, 1, 3)

1 1) 2 (1) (2 6) 5 5 ( 2

z

2

Q ( 2, 0, 0)

x x

y y

z z

1 2 1 2 1 2 M 2, 2, 2

R (0, 0, 0) O

y

1 1

1

25

2 6 5 , 2 2 , 2

K ( 2, 4, 4)

7 3 5 , 10 , 4

L ( 2, 0, 4) M (0, 0, 4)

20. ST (x x1)2 (y2 y1)2 (z2 z1)2 2

x

( 43 6 ) 3 (5 4 ) (2 4 ) 2 2

15.

31

z

R ( 1, 3, 0) O

S (0, 3, 0)

2

17

P ( 2, 4, 0)

N (0, 4, 4)

z z

4 5

3 3 2 1 0, 2, 5

K (4, 1, 0)

14.

y y

03 2 , 2, 2

J (0, 1, 3)

2

2

1 2 1 2 1 2 M 2, 2, 2

y

N (0, 1, 0)

S (0, 4, 0)

(3 0) 0 4 0 3 5 5

10

M (0, 0, 0) O

x H (4, 0, 3)

z z

18. FG (x2 x1)2 (y2 y1)2 (z2 z1)2

z

L (4, 0, 0)

y y

5 8 (2) 2 3 (1) , 2 2 2 , 1 7 7 2, 2, 2

1 2 1 2 1 2 M 2, 2, 2

C (4, 6, 0)

13.

z z

(0, 0, 0)

z

B (4, 0, 0)

y y

2 (2) 2 (2) 0 0 2, 2, 2

1 2 1 2 1 2 M 2, 2, 2

U (3, 0, 1)

x x

y y

z z

1 2 1 2 1 2 M 2, 2, 2

Q ( 1, 0, 0)

2

2

43 5 42 63 , 4 2 2 2 , 2 2 5 53 , 92, 2

y

P (0, 0, 0)

21. BC (x2 (y2 y1)2 (z2 z1)2 x1)2

W ( 1, 3, 6)

(2 3 3)2 (4 2 )2 (4 2 22 )2 x

T (0, 3, 6)

39

V ( 1, 0, 6)

U (0, 0, 6)

x x

y y

z z

1 2 1 2 1 2 M 2, 2, 2

3 2 , 3, 32

23 4 22 3 42 , 2 2 2, 2

Chapter 13

468

22. distance 2 (x x (y2 y1)2 (z2 z1)2 2 1)

The coordinates of the dilated image are G (8, 6, 4), H (8, 0, 4), J (0, 0, 4), K (0, 6, 4), L (8, 6, 0), M (0, 6, 0), N (0, 0, 0), P (8, 0, 0).

2 (240 50)240 (100) 1 (2.5 2)2

z

292.7 The distance is approximately 292.7 miles. 23. First, write a vertex matrix. D

E

H

G

F

x 1 0 0 1 y 0 0 1 1 z 1 1 1 1

1 0 1

0 0 1

0 1 1

1 1 1

A

B

C

K

B

C

H

L

E

H

G

F

1 0 1

0 0 1

0 1 1

1 1 1

E

H G

F

3 0 3

0 0 3

3 3 3

A

B

C

D

0 3 3

P

Coordinates of the Translated coordinates, vertices, (x, y, z) (x 2, y 5, z 5) Preimage Image P(2, 3, 3)

P (0, 2, 2)

Q(2, 0, 3)

Q (0, 5, 2)

z

R(0, 0, 3)

R (2, 5, 2)

H

S(0, 3, 3)

S (2, 2, 2)

T(2, 0, 0)

T (0, 5, 5)

U(2, 3, 0)

U (0, 2, 5)

V(0, 3, 0)

V (2, 2, 5)

W(0, 0, 0)

W (2, 5, 5)

G E

F O

y

B

26. Write the coordinates of each corner. Then use the translation equation (x, y, z) → (x 2, y 1, z 1) to find the coordinates of each vertex of the rectangular prism.

C

x

A

D

Coordinates of the Translated coordinates, vertices, (x, y, z) (x 2, y 1, z 1) Preimage Image

24. First, write a vertex matrix. G

H

J

x 4 y 3 z 2

4 0 2

0 0 4 0 0 3 3 3 2 2 0 0

K

L

M

N

P

0 4 0 0 0 0

Next, multiply each element by the scale factor, 2. G

4 2 3 2

H

J

K

L

M

N

P

4 0 2

0 0 4 0 0 3 3 3 2 2 0 0

0 0 0

4 0 0

M

N

P

0 0 0

8 0 0

G

H

J

8 6 4

8 0 4

0 0 8 0 0 6 6 6 4 4 0 0

4

25. Write the coordinates of each corner. Then use the translation equation (x, y, z) → (x 2, y 5, z 5) to find the coordinates of each vertex of the rectangular prism.

The coordinates of the dilated image are A (3, 0, 3), B (0, 0, 3), C (0, 3, 3), D (3, 3, 3), E (3, 0, 3), H (0, 0, 3), G (0, 3, 3), and F (3, 3, 3).

4

4 y

x

D

3 0 0 3 0 0 3 3 3 3 3 3

N O

G

1 0 0 1 0 0 1 1 3 1 1 1 1

4

4

M

Next, multiply each element by the scale factor, 3. A

J 4

K

L

469

A(2, 0, 1)

A (0, 1, 0)

B(2, 0, 0)

B (0, 1, 1)

C(2, 1, 0)

C (0, 2, 1)

D(2, 1, 1)

D (0, 2, 0)

E(0, 0, 1)

E (2, 1, 0)

F(0, 1, 1)

F (2, 2, 0)

G(0, 1, 0)

G (2, 2, 1)

H(0, 0, 0)

H (2, 1, 1)

Chapter 13

27. Write the coordinates of each corner. Then use the translation equation (x, y, z) → (x 1, y 2, z 2) to find the coordinates of each vertex of the cube.

29. Write a vertex matrix and multiply it by the scale factor, 2. A B C D E F G H

Coordinates of the Translated coordinates, vertices, (x, y, z) (x 1, y 2, z 2) Preimage Image A(3, 3, 3)

A (4, 5, 1)

B(3, 0, 3)

B (4, 2, 1)

C(0, 0, 3)

C (1, 2, 1)

D(0, 3, 3)

D (1, 5, 1)

E(3, 3, 0)

E (4, 5, 2)

F(3, 0, 0)

F (4, 2, 2)

G(0, 0, 0)

G (1, 2, 2)

H(0, 3, 0)

H (1, 5, 2)

z

C

A G

A B

F

E

x

y

H

G E

28. Write the coordinates of each corner. Then use the translation equation (x, y, z) → (x 2, y 3, z 2) to find the coordinates of each vertex of the cube.

B (1, 3, 5)

C(0, 0, 3)

C (2, 3, 5)

D(0, 3, 3)

D (2, 0, 5)

E(3, 3, 0)

E (1, 0, 2)

F(3, 0, 0)

F (1, 3, 2)

G(0, 0, 0)

G (2, 3, 2)

H(0, 3, 0)

H (2, 0, 2)

C

z

B

The coordinates of the dilated image are A (1, 1, 1), B (1, 0, 1), C (0, 0, 1), D (0, 1, 1), E (1, 1, 0), F (1, 0, 0), G (0, 0, 0), and H (0, 1, 0). z

C

D D

C

B B G G

A

A H

F

H

y

E

D

H

C A O

E

x

D The scale factor is 1 3 , so the ratio of the volumes for these two cubes is

H

3 volume of new cube 1 1 2 7. 33 volume of original cube

y

E

x

Chapter 13

A B C D E F G H

F

G

F

E

E F

E

3 3 0 0 3 3 0 0 1 1 0 0 1 1 0 0 1 3 0 0 3 3 0 0 3 1 0 0 1 1 0 0 1 3 3 3 3 3 0 0 0 0 1 1 1 1 0 0 0 0

A G

y

H

A B C D E F G H

Coordinates of the Translated coordinates, vertices, (x, y, z) (x 2, y 3, z 2) Preimage Image A(3, 3, 3) A (1, 0, 5) B(3, 0, 3)

H

O

side length of dilated cube 6 units V s3 63 216 units3 30. Write a vertex matrix and multiply it by the scale factor 1 3.

A

F

B

G

F

x

H

B

A

F D

O

D

B

D C

D C

z

B

The coordinates of the dilated image are A (6, 6, 6), B (6, 0, 6), C (0, 0, 6), D (0, 6, 6), E (6, 6, 0), F (6, 0, 0), G (0, 0, 0), and H (0, 6, 0).

G

C

A B C D E F G H

3 3 0 0 3 3 0 0 6 6 0 0 6 6 0 0 2 3 0 0 3 3 0 0 3 6 0 0 6 6 0 0 6 3 3 3 3 0 0 0 0 6 6 6 6 0 0 0 0

470

31. first balloon location: (12, 12, 0.4) second balloon location: (4, 10, 0.3)

36. The cube extends from x 2 4 2 to x 2 4 6, from y 4 4 0 to y 4 4 8, and from z 6 4 2 to z 6 4 10. So the coordinates of the vertices are A(2, 0, 2), B(6, 0, 2), C(6, 8, 2), D(2, 8, 2), E(2, 8, 10), F(6, 8, 10), G(6, 0, 10), and H(2, 0, 10).

x1)2 (y2 y1)2 (z2 z1)2 distance (x 2 2 [ [4 (12)] 10 (12 )]2 [ 0.3 0.4]2 8.2 The distance between the balloons is approximately 8.2 miles.

x1 x2 y1 y2 z1 z2 32. M 2, 2, 2 2x 4y 7z (5, 1, 2) 22 , 22 , 22 2x 4y 5 ¬22 1 ¬22

z

H

x x

y y

2

2

F

G 7z

A

2 ¬22

O 2

B

2

10 y

2 z

2 ¬22

6 ¬22

8 8 x2

4 ¬10 y2

12 ¬2 z2

C

4 x

1 2 1 2 1 2 M 2, 2, 2

4 22

y

37. Sample answer: Three-dimensional graphing is used in computer animation to render images and allow them to move realistically. Answers should include the following. • Ordered triples are a method of locating and naming points in space. An ordered triple is unique to one point. • Applying transformations to points in space would allow an animator to create realistic movement in animation.

z z

8 x 10 y 2 z (4, 2, 6) 2, 2, 2

D

2

10 ¬2 x2 2 ¬4 y2 4 ¬7 z3 8 ¬x2 2 ¬y2 3 ¬z3 Point B has coordinates (8, 2, 3). 33. The center of the sphere is the midpoint of the diameter.

8x

E

0 x2 14 ¬y2 14 ¬z2 The other endpoint has coordinates (0, 14, 14). 34. Use the midpoint formula with the endpoints of the diameter.

38. C;

x1 x2 y1 y2 z1 z2 M ¬ 2, 2, 2

12 14 8 2 center , 10 2 , 12 2 2

x x

y y

2

5x

4 22

¬(1, 1, 7) The radius is the distance from the center (1, 1, 7) to (14, 8, 2). Let the center be the point (xc, yc, zc).

z z

5 x 4 y 2 z (4, 5, 3) 2, 2, 2 1 2 1 2 1 2 M 2, 2, 2 2

4 y

5 ¬22

2

2 z

3 22

8 5 x2 10 4 y2 6 2 z2 3 x2 6 ¬y2 8 z2 The other endpoint has coordinates (3, 6, 8). 39. B; x 1 ¬x 1 x 1 ¬(x 1)2 x 1 ¬x2 2x 1 0 ¬x2 3x 0 ¬x (x 3) x 0 or x 3 Check if each value satisfies the original equation. 0 1 ¬0 1 3 1 ¬3 1 1 ¬1 4 ¬2 ✓ 1 ¬1 2 ¬2 So the solution is x 3. 40. The locus of points in space that satisfy the graph of x y 5 is a plane perpendicular to the xy-plane whose intersection with the xy-plane is the graph of y x 5. 41. The locus of points in space that satisfy the graph of x z 4 is a plane perpendicular to the xz-plane whose intersection with the xz-plane is the graph of z x 4.

(x2 xc)2 (y2 yc)2 (z2 zc)2 radius (14 1)2 (8 1)2 (2 7 )2 275 or 511 35. The prism has moved down 5 units, right 3 units, and forward 2 units. (x, y, z) → (x 2, y 3, z 5)

471

Chapter 13

Page 719


Pages 720–722 Lesson-by-Lesson Review 11. V Bh (18)(7)(4) 504 The volume of the prism is 504 in3. 12. V r2h (32)(11) 311.0 The volume is approximately 311.0 m3. 13. The 15-ft diagonal forms a right triangle with the height and width. Use the Pythagorean Theorem to find the width. a2 b2 ¬c2 w2 32 ¬152 w2 9 ¬225 w2 ¬216 w ¬66 ft Now find the volume. V Bh (17)(66 )(3) 749.5 The volume is approximately 749.5 ft3. 14. First find the area of the hexagonal base.

width of smaller prism 9 42. 18 width of larger prism 1 2 height of smaller prism 7 13 height of larger prism

Since the ratios are not the same, the prisms are neither similar nor congruent. 5 2 43. 15 diameter of larger cylinder diameter of smaller cylinder

2 3 height of smaller cylinder 12 18 height of larger cylinder 2 3

The two cylinders are similar. Since the scale factor is not 1, they are not congruent. 3 44. V 4 3 r 3 4 3 (10 )

4188.8 The volume is approximately 4188.8 cm3. 45. radius 1 2 (13) 6.5 yd 4 3 V 3 r 3 4 3 (6.5 )

1150.3 The volume is approximately 1150.3 yd3. 3 46. V 4 3 r

30

3 4 3 (17.2 )

21,314.4 The volume is approximately 21,314.4 m3.

3 1.5

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The shorter leg of the triangle is 1 2 (3) or 1.5. The apothem is the longer leg of the triangle or 1.53 . perimeter 3 6 18

47. radius 1 2 (29) 14.5 ft 3 V 4 3 r

3 4 3 (14.5 )

12,770.1 The volume is approximately 12,770.1 ft3.

Area: A ¬1 2 Pa 1 ¬2(18)(1.53 )


¬13.53 Now find the volume of the pyramid.

Page 720 Vocabulary and Concept Check 1. 2. 3. 4. 5. 6. 7. 8. 9. 10.

V ¬1 3 Bh

pyramid Congruent an ordered triple cylinder similar prism the Distance Formula in Space sphere Cavalieri’s Principle cone

Chapter 13

¬1 )(14) 3 (13.53

¬109.1 The volume is approximately 109.1 cm3. 15. radius 1 2 (15) 7.5 Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 7.52 h2 262 56.25 h2 ¬676 h2 ¬619.75 h ¬619.7 5

472

Now solve for . 232 ¬22 56 176 ¬22 8 ¬ For the right solid, the surface area is T ¬Ph 2B 232 ¬2(8 7)(h) 2(8 7) Now solve for h. 232 ¬30h 112 120 ¬h 4 ¬h The solids have the same dimensions, so they are congruent. 23. Two spheres with different radii are similar, though not congruent. 24. AB (x2 x1)2 (y2 y1)2 (z2 z1)2

For the cone, 2 V 1 3 r h 2 ¬1 5 ) 3 (7.5 )(619.7

¬1466.4 The volume is approximately 1466.4 ft3. 16. V ¬1 3 Bh ¬1 3 (17)(5)(13)

¬368.3 The volume is approximately 368.3 m3. 3 17. V ¬4 3 r 3 ¬4 3 (2 )

¬33.5 The volume is approximately 33.5 ft3. 18. radius 1 2 (4) 2

[3 ( 5)]2 [8 ( 8)]2 [4 (2)]2 100 10

3 V ¬4 3 r 3 ¬4 3 (2 )

y y

z z

5 3 8 (8) 4 ¬ , 2, 22 2

¬33.5 The volume is approximately 33.5 ft3. 19. Find the radius. C ¬2 r 65 ¬2 r

¬(1, 8, 1) 25. CD (x2 x1)2 (y2 y1)2 (z2 z1)2 ¬ [9 (9)]2 [9 2]2 [7 4]2 ¬58

65 ¬r 2

x x

y y

z z

1 2 1 2 1 2 M 2, 2, 2

Now find the volume. 3 V ¬4 3 r 3 65 ¬4 3 2

9 (9) 9 47 ¬ , 2 2, 2 2

¬(9, 5.5, 5.5) 26. EO ¬(x x1)2 (y2 y1)2 (z2 z1)2 2

¬4637.6 The volume is approximately 4637.6 mm3. 20. Find the radius. T ¬4 r2 126 ¬4 r2

¬ (4 0)2 (5 0 )2 (5 0)2 ¬66

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

0 50 4 0 ¬ , 5 2, 2 2

63 ¬r2 2 63 2 ¬r

¬(2, 2.5, 2.5) 27. FG (x2 x1)2 (y2 y1)2 (z2 z1)2

Now find the volume. 3 V ¬4 3 r 63 ¬4 2 3

x x

1 2 1 2 1 2 M ¬ 2, 2, 2

2 ( (2 5 2 )2 ( 2 37 37 ) 12 6 )2 422

3

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

¬133.0 The volume is approximately 133.0 cm3. 21. Find the radius. A ¬ r2 25 ¬ r2 25 ¬r2 5 ¬r Now find the volume.

22 37 52 6 (12) ¬ , 37 , 2 2 2

¬(1.52 , 37 , 3)


3 V ¬4 3 r 3 ¬4 3 (5 )

Page 723 1. b 2. c 3. a

¬523.6 The volume is approximately 523.6 units3. 22. For the left solid, the surface area is T ¬Ph 2B 232 2( 7)(4) 2( 7)

473

Chapter 13

4. The diameter of the base, the diagonal, and the lateral edge form a right triangle. Find the diameter using the Pythagorean Theorem. a2 b2 ¬c2 82 d2 ¬102 64 d2 ¬100 d2 ¬36 d ¬6 yd radius 1 2 (6) 3 Now find the volume, using the formula for a cylinder. V ¬ r2h ¬ (32)(8) ¬226.2 The volume is approximately 226.2 yd3. 5. Use the formula for a rectangular prism. V ¬Bh ¬(6)(14)(10) ¬840 The volume of the prism is 840 mm3. 6. Find the width using the Pythagorean Theorem. a2 b2 ¬c2 72 w2 (74 )2 49 w2 ¬74 w2 ¬25 w ¬5 Now find the volume, using the formula for a rectangular prism. V ¬Bh ¬(7)(5)(2) ¬70 The volume of the prism is 70 km3. 7. Use the formula for a pyramid.

Find the height using the Pythagorean Theorem and the fact that for a regular hexagon the distance from the center to a vertex is the same as the side length.

13

h

5

¬c2 2 h ¬132 25 h2 ¬169 h2 ¬144 h ¬12 m Now find the volume. a2

b2

52

V ¬1 3 Bh ¬31 (37.53 )(12)

¬259.8 The volume is approximately 259.8 m3. 9. Use the formula for a cone. radius 1 2 (8.2) 4.1 2 V ¬1 3 r h 2 ¬1 3 (4.1 )(6.8)

¬119.7 The volume is approximately 119.7 cm3. 10. Use the formula for an oblique cone. First find the radius. C ¬2 r 22 ¬2 r 11 ¬r Now find the volume.

V ¬1 3 Bh ¬1 3 (5)(5)(3)

¬25 The volume of the pyramid is 25 ft3. 8. First find the area of the hexagonal base.

V ¬1 3 Bh ¬31 r2h 2 ¬1 3 (11 )(9)

¬1140.4 The volume is approximately 1140.4 in3. 11. The length, the width, and the diagonal form a right triangle. Use the Pythagorean Theorem to find the width w. a2 b2 c2 782 w2 110.32 6084 w2 ¬12,166.09 w2 ¬6082.09 w ¬77.98776 ft

30 5

2.5

Apothem: A 30°-60°-90° triangle is formed by the apothem and one-half of a side of the hexagon. The shorter leg of the triangle is 1 2 (5) or 2.5. The apothem is the longer leg of the triangle or 2.53 . perimeter 5 6 30 Area: A ¬1 2 Pa ¬1 ) 2 (30)(2.53

¬37.53

Chapter 13

474

Consider the water as a rectangular prism. Now find the volume in cubic feet, multiplied by a conversion factor of 71 2 gallons per cubic foot.

surface area of larger cylinder

2

17. ¬a b2 surface area of smaller cylinder 2

15 ¬ 10

V ¬Bh71 2

2

¬3 2

¬(78)(77.98776)(17)(7.5) ¬775,588 The volume of water is approximately 775,588 gal.

2

¬3 22 ¬9 4 The ratio of the surface areas is 9 : 4.

3 12. V ¬4 3 r 3 ¬4 3 (3 )

3

volume of larger cylinder

a 18. volume of smaller cylinder ¬ b3 3

15 ¬ 10

¬113.1 The volume is approximately 113.1 cm3. 13. Find the radius. C ¬2 r 34 ¬2 r

3

¬3 2 3

¬3 23 2 7 ¬ 8 The ratio of the volumes is 27 : 8.

17 ¬r

Now find the volume.

19. d ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

3 V ¬4 3 r 3 17 ¬4 3

¬ (0 0 )2 ( 3 0 )2 (5 0)2 ¬34

¬663.7 The volume is approximately 663.7 ft3. 14. Find the radius. T ¬4 r2 184 ¬4 r2

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

0 0 (3) 0 5 0 ¬ 2 , 2, 2

¬(0, 1.5, 2.5) 20. d ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

46 2 ¬r

¬ (1 0)2 (10 0)2 (5 0)2 ¬126 or 314

r ¬3.8265 Now find the volume.

3 V ¬4 3 r 3 ¬4 3 (3.8265 )

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

0 (1) 10 0 (5) 0 ¬ , 2 , 2 2

¬234.7 The volume is approximately 234.7 in3. 15. Find the radius. A ¬ r2 157 ¬ r2

¬(0.5, 5, 2.5) 21. d ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2 ¬ (9 0 )2 (5 0)2 ( 7 0 )2 ¬155

157 2 ¬r

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

r ¬7.06928 Now find the volume.

9 0 5 0 (7) 0 ¬ 2 , 2, 2

¬(4.5, 2.5, 3.5)

3 V ¬4 3 r 3 ¬4 3 (7.06928 )

22. d ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2 ¬ [3 (2)]2 [ 5 2 ]2 [ 4 2 ]2 ¬86

¬1479.8 The volume is approximately 1479.8 mm3.

radius of larger cylinder

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

16. radius of smaller cylinder

2 (3) 2 (5) 2 (4) ¬ , , 2 2 2

height of larger cylinder

height of smaller cylinder

¬(2.5, 1.5, 1)

15 10

23. d ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

3 2 The ratio of the radii is 3 : 2.

¬ (9 9)2 (7 3)2 (6 4)2 ¬428 or 2107

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

9 37 46 9 ¬ 2 , 2, 2

¬(0, 2, 5)

475

Chapter 13

24. d ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

z z 12 27 6 z 12z 27z 6z 9. 3z 3z 3z 3z 4z4 9z 2 10. Sierra: p → q Carlos: q → p Carlos formed the contrapositive. 11. If the measures of the corresponding sides are the same, the triangles are congruent. 12. From Theorem 8.2, the sum of eight exterior angles is 360, so that one exterior angle 36 0 measures 8 45. 5

¬ (3 8)2 [5 (6)] 2 (10 1)2 ¬323

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

8 (3) 10 6 5 ¬ , 1 2 , 2 2

25. C;

¬(2.5, 0.5, 5.5) V ¬Bh 360 ¬(15)w(2) 360 ¬30w 12 ¬w

B


A

1. A; ACD and ACB together form the right angle, BCD. 2. B; 5x° ¬x° 90° 4x° ¬90° x ¬22.5 and since x mDEF 90, 22.5 mDEF ¬90 mDEF ¬67.5 3. C; the third side length must be greater than 21 13 8 and less than 21 13 33. 4. C; from the statement QRS is similar to TUV, we know that Q and T are corresponding angles. 5. B; volume of drilled block volume of prism volume of cylinder Bh r2h (11)(5)(8) (22)(8) 339.5 cm3 6. B; C ¬2 r 25 ¬2 r

45 x

2

C

x

Because the octagon is regular, AB CB, and ABC is an isosceles triangle, so mA mC. By the Exterior Angle Theorem, mA mC 45 x x ¬45 2x ¬45 x ¬22.5 13. Point A lies on the x-axis, b units to the left of D(0, c) just as B is b units to the right of C. The coordinates of A are (b, 0). 2 14. V ¬1 3 r h 2 ¬1 3 (10 )(18)

¬600 cm3 15a. The surface area of the small can is 54 in2 and the surface area of the large can is 90 in2. When the height is doubled, the lateral area of the cylinder is doubled, but the area of the bases remains the same. The surface area increases by a factor of 12 3 times. 15b. The volume of the small can is 54 in3 and the volume of the larger can is 108 in3. The volume increases by a factor of 2. 16. volume of tank volume of cone volume of cylinder volume of hemisphere 2 2 1 4 3 ¬1 3 r h1 r h2 2 3 r

25 ¬r 2 3 V ¬4 3 r 3 25 4 ¬3 2

¬264 in3 height of larger cylinder 16 7. C; height of smaller cylinder 12 4 3 r ¬4 4.5 3

3r ¬18 r ¬6 V ¬ r2h ¬ (62)(16) ¬1809.6 cm3 8. D; r ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

2 2 3 2 ¬1 3 (5 )(15) (5 )(45) 3 (5 )


2 ( ¬ (9 3) 2 1 )2 ( 2 4 )2 ¬9

Chapter 13

5

2

476

Prerequisite Skills 16–31. Graph for Ex. 16–31:

Pages 728–729 Graphing Ordered Pairs 1. The x-coordinate is 2. The y-coordinate is 3. The ordered pair is (2, 3). 2. The x-coordinate is 1. The y-coordinate is 1. The ordered pair is (1, 1). 3. The x-coordinate is 2. The y-coordinate is 2. The ordered pair is (2, 2). 4. The x-coordinate is 3. The y-coordinate is 3. The ordered pair is (3, 3). 5. The x-coordinate is 3. The y-coordinate is 1. The ordered pair is (3, 1). 6. The point lies on the y-axis, so its x-coordinate is 0. The y-coordinate is 3. The ordered pair is (0, 3). 7. The x-coordinate is 4. The y-coordinate is 1. The ordered pair is (4, 1). 8. The x-coordinate is 3. The y-coordinate is 2. The ordered pair is (3, 2). 9. The x-coordinate is 1. The y-coordinate is 1. The ordered pair is (1, 1). 10. The x-coordinate is 1. The y-coordinate is 4. The ordered pair is (1, 4). 11. The x-coordinate is 3. The point lies on the x-axis, so its y-coordinate is 0. The ordered pair is (3, 0). 12. The x-coordinate is 2. The y-coordinate is 4. The ordered pair is (2, 4). 13. The x-coordinate is 2. The y-coordinate is 4. The ordered pair is (2, 4). 14. The x-coordinate is 3. The y-coordinate is 3. The ordered pair is (3, 3). 15. The x-coordinate is 4. The y-coordinate is 2. The ordered pair is (4, 2).

y

T D

M

E

A

G

C N O

H

x

S B

R

F

I

L P 16. Start at the origin. Move 1 unit left, since the x-coordinate is 1. Then move 3 units up, since the y-coordinate is 3. Draw a dot, and label it M. Point M(1, 3) is in Quadrant II. 17. Start at the origin. Move 2 units right, since the x-coordinate is 2. Since the y-coordinate is 0, the point lies on the x-axis. Draw a dot, and label it S. Because it is on one of the axes, point S(2, 0) is not in any quadrant. 18. Start at the origin. Move 3 units left, since the x-coordinate is 3. Then move 2 units down, since the y-coordinate is 2. Draw a dot, and label it R. Point R(3, 2) is in Quadrant III. 19. Start at the origin. Move 1 unit right, since the x-coordinate is 1. Then move 4 units down, since the y-coordinate is 4. Draw a dot, and label it P. Point P(1, 4) is in Quadrant IV. 20. Start at the origin. Move 5 units right, since the x-coordinate is 5. Then move 1 unit down, since the y-coordinate is 1. Draw a dot, and label it B. Point B(5, 1) is in Quadrant IV. 21. Start at the origin. Move 3 units right, since the x-coordinate is 3. Then move 4 units up, since the y-coordinate is 4. Draw a dot, and label it D. Point D(3, 4) is in Quadrant I. 22. Start at the origin. Move 2 units right, since the x-coordinate is 2. Then move 5 units up, since the y-coordinate is 5. Draw a dot, and label it T. Point T(2, 5) is in Quadrant I. 23. Start at the origin. Move 4 units left, since the x-coordinate is 4. Then move 3 units down, since the y-coordinate is 3. Draw a dot, and label it L. Point L(4, 3) is in Quadrant III. 24. Start at the origin. Move 2 units left, since the x-coordinate is 2. Then move 2 units up, since the y-coordinate is 2. Draw a dot, and label it A. Point A(2, 2) is in Quadrant II. 25. Start at the origin. Move 4 units right, since the x-coordinate is 4. Then move 1 unit up, since the y-coordinate is 1. Draw a dot, and label it N. Point N(4, 1) is in Quadrant I. 26. Start at the origin. Move 3 units left, since the x-coordinate is 3. Then move 1 unit down, since the y-coordinate is 1. Draw a dot, and label it H. Point H(3, 1) is in Quadrant III.

477

Prerequisite Skills

27. Start at the origin. Since the x-coordinate is 0, the point lies on the y-axis. Move 2 units down, since the y-coordinate is 2. Draw a dot, and label it F. Because it is on one of the axes, point F(0, 2) is not in any quadrant. 28. Start at the origin. Move 3 units left, since the x-coordinate is 3. Then move 1 unit up, since the y-coordinate is 1. Draw a dot, and label it C. Point C(3, 1) is in Quadrant II. 29. Start at the origin. Move 1 unit right, since the x-coordinate is 1. Then move 3 units up, since the y-coordinate is 3. Draw a dot, and label it E. Point E(1, 3) is in Quadrant I. 30. Start at the origin. Move 3 units right, since the x-coordinate is 3. Then move 2 units up, since the y-coordinate is 2. Draw a dot, and label it G. Point G(3, 2) is in Quadrant I. 31. Start at the origin. Move 3 units right, since the x-coordinate is 3. Then move 2 units down, since the y-coordinate is 2. Draw a dot, and label it I. Point I(3, 2) is in Quadrant IV. 32. Graph the ordered pairs on a coordinate plane. Connect each pair of consecutive points. The polygon is a square.

35. Graph the ordered pairs on a coordinate plane. Connect each pair of consecutive points. The polygon is a rectangle. y

R( 2, 1)

S(4, 1) O

Q (4, 1)

36. Make a table. Choose four values for x. Evaluate each value of x for 2x. x

2x

y

(x, y)

1

2(1)

2

(1, 2)

0

2(0)

0

(0, 0)

1

2(1)

2

(1, 2)

2

2(2)

4

(2, 4)

y

y

W ( 3, 3)

x

P ( 2, 1)

(2, 4)

Y ( 1, 3)

(1, 2) O

O (0, 0)

x

Z ( 1, 1)

X ( 3, 1)

( 1, 2)

37. Make a table. Choose four values for x. Evaluate each value of x for 1 x.

33. Graph the ordered pairs on a coordinate plane. Connect each pair of consecutive points. The polygon is a square. y M ( 1, 5)

L( 2, 2)

J ( 4, 2) O

x

x

K ( 1, 1)

x

1x

y

(x, y)

0

10

1

(0, 1)

1

11

2

(1, 2)

2

12

3

(2, 3)

3

13

4

(3, 4)

y (3, 4)

34. Graph the ordered pairs on a coordinate plane. Connect each pair of consecutive points. The polygon is a triangle. y

(0, 1) O

F(2, 4)

G( 3, 2)

O

x

H( 1, 3)

Prerequisite Skills

478

(2, 3) (1, 2) x

38. Make a table. Choose four values for x. Evaluate each value of x for 3x 1. x

3x 1

y

(x, y)

1

3(1) 1

4

(1, 4)

0

3(0) 1

1

(0, 1)

1

3(1) 1

2

(1, 2)

2

3(2) 1

5

(2, 5)

7. Since the liquid in a cup is a small amount, the milliliter is the appropriate unit of measure. 8. Since the water in a bath tub is a large amount, the liter is the appropriate unit of measure. 9. There are 12 inches in a foot. 120 in. 12 10 ft 10. There are 3 feet in a yard. 18 ft 3 6 yd 11. There are 1000 meters in a kilometer. 10 km 1000 10,000 m 12. There are 10 millimeters in a centimeter. 210 mm 10 21 cm 13. There are 100 centimeters in a meter. First change millimeters to centimeters. 180 mm¬ ? cm 180 mm 10¬ 18 cm Then change centimeters to meters. 18 cm¬ ? m 18 cm 100¬ 0.18 m 14. There are 1000 meters in a kilometer. 3100 m 1000 3.1 km 15. There are 3 feet in a yard. First change inches to feet. 90 in.¬ ? ft 90 in. 12¬ 7.5 ft Then change feet to yards. 7.5 ft¬ ? yd 7.5 ft 3¬ 2.5 yd 16. There are 5280 feet in one mile. First change yards to feet. 5280 yd¬ ? ft 5280 yd 3¬ 15,840 ft Then change feet to miles. 15,840 ft¬ ? mi 15,840 ft 5,280¬ 3 mi 17. There are 3 feet in a yard. 8 yd 3 24 ft 18. There are 1000 meters in a kilometer. 0.62 km 1000 620 m 19. There are 1000 milliliters in a liter. 370 mL 1000 0.370 L 20. There are 1000 milliliters in a liter. 12 L 1000 12,000 mL 21. There are 8 fluid ounces in a cup. 32 fl oz 8 4 c 22. There are 2 pints in one quart. First change quarts to pints. 5 qt¬ ? pt 5 qt 2¬ 10 pt Then change pints to cups. 10 pt¬ ? c 10 pt 2¬ 20 c 23. There are 2 pints in a quart. 10 pt 2 5 qt 24. There are 4 quarts in one gallon. First change cups to pints. 48 c¬ ? pt 48 c 2¬ 24 pt

y (2, 5)

(1, 2) x

O (0, 1)

( 1, 4)

39. Make a table. Choose four values for x. Evaluate each value of x for 2 x. x

2x

y

(x, y)

1

2 (1)

3

(1, 3)

0

20

2

(0, 2)

1

21

1

(1, 1)

2

22

0

(2, 0)

y ( 1, 3) (0, 2) O

(1, 1) (2, 0) x

Pages 730–731 Changing Units of Measure within Systems 1. Since a tennis ball has a small radius, the centimeter is the appropriate unit of measure. 2. Since a notebook has a small length, the centimeter is the appropriate unit of measure. 3. Since a textbook has a fairly heavy mass, the kilogram is the appropriate unit of measure. 4. Since a beach ball has a light mass, the gram is the appropriate unit of measure. 5. Since a football field has a long width, the meter is the appropriate unit of measure. 6. Since a penny has a very small thickness, the millimeter is the appropriate unit of measure.

479

Prerequisite Skills

25. 26. 27. 28. 29.

6. P 4s 4(5.3) 21.2 A s2 (5.3)2 28.09 The perimeter is 21.2 meters, and the area is 28.09 square meters. 7. P 2( w) 2(7 11) 36 A w 7 11 77 The perimeter is 36 meters, and the area is 77 square meters. 8. P 4s 4(4.5) 18 A s2 (4.5)2 20.25 The perimeter is 18 inches, and the area is 20.25 square inches. 9. P 2( w) 2(2.4 1.6) 8 A w (2.4)(1.6) 3.84 The perimeter is 8 meters, and the area is 3.84 square meters. 10. P 4s 4(6.5) 26 A s2 (6.5)2 42.25 The perimeter is 26 yards, and the area is 42.25 square yards. 11. P 4s 4(12) 48 A s2 122 144 The perimeter is 48 feet, and the area is 144 square feet. 12. P 2( w) 2(4.2 15.7) 39.8 A w (4.2)(15.7) 65.94 The perimeter is 39.8 inches, and the area is 65.94 square inches. 13. P 4s 4(18) 72

Then change pints to quarts. 24 pt¬ ? qt 24 2¬ 12 qt Then change quarts to gallons. 12 qt¬ ? gal 12 qt 4¬ 3 gal There are 4 quarts in a gallon. 4 gal 4 16 qt There are 1000 milligrams in a gram. 36 mg 1000 0.036 g There are 16 ounces in a pound. 13 lb 16 208 oz There are 1000 grams in a kilogram. 130 g 1000 0.130 kg There are 1000 grams in a kilogram. 9.05 kg 1000 9050 g

Pages 732–733 Perimeter and Area of Rectangles and Squares 1. P ¬4s ¬4(11) ¬44 A ¬s2 ¬112 ¬121 The perimeter is 44 inches, and the area is 121 square inches. 2. P 2( w) 2(7.5 3) 21 A w 7.5 3 22.5 The perimeter is 21 kilometers, and the area is 22.5 square kilometers. 3. P 4s 4(3.5) 14 A s2 (3.5)2 12.25 The perimeter is 14 yards, and the area is 12.25 square yards. 4. P 2( w) 2(4 2.5) 13 A w 4 2.5 10 The perimeter is 13 feet, and the area is 10 square feet. 5. P 2( w) 2(5.7 1.8) 15 A w 5.7 1.8 10.26 The perimeter is 15 centimeters, and the area is 10.26 square centimeters.

Prerequisite Skills

480

21. 4 6 4 6 4 (6) 2 22. 7 1 7 1 8 23. 1 2 1 2 3 24. 2 5 2 5 2 (5) 3 25. 5 2 |3| 3 26. 6 4 |10| 10 27. 3 7 3 (7) 4 4 28. 3 3 3 (3) 6 6 29. 36 9 4 30. 3(7) 21 31. 6(4) 24 32. 25 5 5 33. 6(3) 18 34. 7(8) 56 35. 40 (5) 8 36. 11(3) 33 37. 44 (4) 11 38. 63 (7) 9 39. 6(5) 30 40. 7(12) 84 41. 10(4) 40 42. 80 (16) 5 43. 72 9 8 44. 39 3 13

A s2 182 324 The perimeter is 72 centimeters, and the area is 324 square centimeters. 14. P 2( w) 2(5.3 7) 24.6 A w 5.3 7 37.1 The perimeter is 24.6 feet, and the area is 37.1 square feet. 15. P 2( w) 2(360 121) 962 Jansen needs 962 feet of fence. 16. Find the area of the room and compare it to 105 square feet. A w 11 10 110 Leonardo’s bedroom is 110 square feet. Since 110 105, the remnant cannot be used to cover his bedroom floor.

Pages 734–735 Operations with Integers 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20.

3 3 4 4 0 0 5 5 4 5 4 (5) 9 347 9 5 9 (5) 4 2 5 2 (5) 7 3 5 3 (5) 2 6 11 5 4 (4) 8 5 9 5 (9) 4 3 1 2 4 (2) 6 2 (8) 2 8 10 7 (3) 4 4 (2) 4 2 2 3 (3) 3 3 6 3 (4) 1 3 (9) 3 9 6

Page 736 Evaluating Algebraic Expressions 1. 2a c 2(2) (1) 4 (1) 3 (3)(4) bd 2. 2 c ¬ 2(1) 1 2 ¬ 2

¬6

2(4) 2 2d a 3. ¬ 3 b 82 ¬ 3 6 ¬ 3

¬¬2 4. 3d c 3(4) (1) 12 (1) 12 1 13

481

Prerequisite Skills

3(3)

3b ¬ 5. 5a 5(2) (1) c 9 ¬ 10 (1)

3.

9 ¬ 9

8a ¬6 5 5 8 a ¬5(6) 8 5 8 1 5 a ¬ 4 p 5. 1 2 ¬6 p 12 1 2 ¬12(6)

4.

¬1 6. 5bc 5(3)(1) 15(1) 15 7. 2cd 3ab 2(1)(4) 3(2)(3) 2(4) 6(3) 8 (18) 26

p ¬72 x 4 ¬8 6. x 4 4 ¬4 8

1 2(4) c 2d 8. ¬2 a 1 8 ¬ 2

x ¬32

9 ¬ 2

12 f ¬18 5 5 12 5 12 5 f ¬ 1 2 (18) 15 f ¬2 y 7 ¬11 8.

7.

¬9 2

9. 24 x 4 24 2 4 24 2 24 2 26 10. 13 8 y 13 8 (3) 13 5 13 5 18 11. 5 z 11 5 1 11 4 11 4 11 15 12. 2y 15 7 2(3) 15 7 6 15 7 21 7 21 7 28 13. y 7 3 7 37 4 14. 11 7 x 11 7 2 11 7 2 42 6 15. x 2z 2 2(1) 2 2 22 0 16. z y 6 1 (3) 6 1 3 6 4 6 46 10

77 ¬7(11) y

y ¬77 9.

10.

11.

12.

13.

14.

15.

6y ¬3 7 7 6 y ¬7(3) 6 7 6 y ¬7 2

c 14 ¬11 c 14 14 ¬11 14 c ¬3 t 14 ¬29 t 14 14 ¬29 14 t ¬15 p 21 ¬52 p 21 21 ¬52 21 p ¬73 b 2 ¬5 b 2 2 ¬5 2 b ¬7 q 10 ¬22 q 10 10 ¬22 10 q ¬12 12q ¬84 12q 84 ¬ 1 12 2

q ¬7 16. 5s ¬30 s 3 0 5 5 ¬ 5

17.

Pages 737–738 Solving Linear Equations r 11 ¬3 r 11 11 ¬3 11 r ¬8 2. n 7 ¬13 n 7 7 ¬13 7 n ¬6 1.

Prerequisite Skills

d 7 ¬8 d 7 7 ¬8 7 d ¬15

482

s ¬6 5c 7 ¬8c 4 5c 7 7 ¬8c 4 7 5c ¬8c 3 5c 8c ¬8c 3 8c 3c ¬3 3 c 3 3 ¬ 3 c ¬1

18.

19.

2 6 ¬6 10 2 6 6 ¬6 10 6 2 ¬6 16 2 6 ¬6 16 6 4 ¬16 4 1 6 4 ¬ 4 ¬4

27.

x ¬21

m 1 0 15 ¬21

28.

m 1 0 15 15 ¬21 15 m 1 0 ¬6 m 10 1 0 ¬10 6

g ¬6 4 p ¬2 4 p 4 ¬2 4 p ¬2 p ¬2 30. 21 b ¬11 21 b 21 ¬11 21 b ¬10 b ¬10 31. 2(n 7) ¬15 2n 14 ¬15 2n 14 14 ¬15 14 2n ¬29 29.

m 8 7 ¬5 m 8 7 7 ¬5 7 m 8 ¬2 8m 8 ¬8(2)

m ¬16 21. 8t 1 ¬3t 19 8t 1 1 ¬3t 19 1 8t ¬3t 20 8t 3t ¬3t 20 3t 5t ¬20 20 5t ¬ 5 5 t ¬4 22. 9n 4 ¬5n 18 9n 4 4 ¬5n 18 4 9n ¬5n 14 9n 5n ¬5n 14 5n 4n ¬14

2 n 29 2 ¬ 2 29 n ¬ 2

5(m 1) ¬25 5m 5 ¬25 5m 5 5 ¬25 5 5m ¬20 5m 20 5 ¬ 5 m ¬4 33. 8a 11 ¬37 8a 11 11 ¬37 11 8a ¬48 32.

4n 14 4 ¬ 4 7 n ¬2

5c 24 ¬4 5c 24 24 ¬4 24 5c ¬20 5 c 2 0 5 ¬ 5 c ¬4 24. 3n 7 ¬28 3n 7 7 ¬28 7 3n ¬21 3n 21 3 ¬ 3 n ¬7 25. 2y 17 ¬13 2y 17 17 ¬13 17 2y ¬30 2 y 3 0 2 ¬ 2 y ¬15 23.

26.

9 4g ¬15 9 4g 9 ¬15 9 4g ¬24 4g 2 4 ¬ 4 4

m ¬60 20.

2x 4 ¬2 9 3 x 4 4 ¬2 4 2 9 3 2 1 4 x ¬ 9 3 1 4 92x ¬9 2 9 2 3

8 a 48 8 ¬ 8

a ¬6 34.

7q 2 ¬5 4 7q 2 2 ¬5 2 4 7q ¬3 4 4 7 q ¬43 7 4 7 12 q ¬ 7

35.

2(5 n) ¬8 10 2n ¬8 10 2n 10 ¬8 10 2n ¬2 2 n 2 2 ¬ 2

t 1 3 2 ¬3 t 1 3 2 2 ¬3 2 t 1 3 ¬5 t 13 1 3 ¬13(5)

36.

n ¬1 3(d 7) ¬6 3d 21 ¬6 3d 21 21 ¬6 21 3d ¬15 3 d 1 5 3 ¬ 3

t ¬65

d ¬5

483

Prerequisite Skills

Pages 739–740 Solving Inequalities in One Variable

11.

x 7 ¬6 x 7 7 ¬6 7 x ¬13 The solution set is {xx 13}. 2. 4c 23 ¬13 4c 23 23 ¬13 23 4c ¬36 c 36 4 4 ¬ 4 c ¬9 The solution set is {cc 9}. p 3. 5 ¬14 1.

12.

13.

55 ¬5(14) p

14.

p ¬70 The solution set is {pp 70}. 4. a 8 ¬5

15.

8a 8 ¬8(5)

a ¬40 The solution set is {aa 40}. t ¬7 5. 6

16.

4y 2 0 ¬ 4 4

66t ¬6(7)

y ¬5 The solution set is {yy 5}. 17. 12k ¬36 6 12 k 3 12 ¬ 12 k ¬3 The solution set is {kk 3}. 18. 4h ¬36

t ¬42 The solution set is {tt 42}. a 6. 1 1 ¬8 a 11 1 1 ¬11(8)

a ¬88 The solution set is {aa 88}. 7. d 8 ¬12 d 8 8 ¬12 8 d ¬4 The solution set is {dd 4}. 8. m 14 ¬10 m 14 14 ¬10 14 m ¬4 The solution set is {mm 4}. 9. 2z 9 ¬7z 1 2z 9 9 ¬7z 1 9 2z ¬7z 10 2z 7z ¬7z 10 7z 5z ¬10

4 h 36 4 ¬ 4

h ¬9 The solution set is {hh 9}.

19.

2b 6 ¬2 5 2b 6 6 ¬2 6 5 2b ¬4 5 52b ¬5(4) 2 5 2

b ¬10 The solution set is {bb 10}. 20.

8t 1 ¬5 3 8t 1 1 ¬5 1 3 8t ¬6 3 3 8 t ¬3(6) 8 3 8 t ¬9 4

5 z 10 5 ¬ 5

z ¬2 The solution set is {zz 2}. 10. 6t 10 ¬4t 6t 10 10 ¬4t 10 6t ¬4t 10 6t 4t ¬4t 10 4t 2t ¬10 10 2t ¬ 2 2 t ¬5 The solution set is {tt 5}.

Prerequisite Skills

3z 8 ¬2 3z 8 8 ¬2 8 3z ¬6 6 3 z 3 ¬ 3 z ¬2 The solution set is {zz 2}. a 7 ¬5 a 7 7 ¬5 7 a ¬12 The solution set is {aa 12}. m 21 ¬8 m 21 21 ¬8 21 m ¬29 The solution set is {mm 29}. x 6 ¬3 x 6 6 ¬3 6 x ¬9 The solution set is {xx 9}. 3b ¬48 3 b 48 3 ¬ 3 b ¬16 The solution set is {bb 16}. 4y ¬20

The solution set is tt 9 4 .

484

21.

7q 3 ¬4q 25 7q 3 3 ¬4q 25 3 7q ¬4q 22 7q 4q ¬4q 22 4q 11q ¬22

2. 2x 5y 10 To find the x-intercepts, let y 0 2x 5y ¬10 2x 5(0) 10 2x ¬10 x ¬5 To find the y-intercept, let x 0 2x 5y ¬10 2(0) 5y ¬10 5y ¬10 y ¬2 Put a point on the x-axis at 5 and a point on the y-axis at 2. Draw a line through the two points.

11q 22 ¬ 11 11

q ¬2 The solution set is {qq 2}. 22. 3n 8 ¬2n 7 3n 8 8 ¬2n 7 8 3n ¬2n 15 3n 2n ¬2n 15 2n 5n ¬15

y

5 n 15 5 ¬ 5

n ¬3 The solution set is {nn 3}. 23. 3w 1 ¬8 3w 1 1 ¬8 1 3w ¬7

2x

x

3. 3x y 3 To find the x-intercept, let y 0. 3x y ¬3 3x 0 ¬3 3x ¬3 x ¬1 To find the y-intercept, let x 0. 3x y ¬3 3(0) y ¬3 y ¬3 y ¬3 Put a point on the x-axis at 1 and a point on the y-axis at 3. Draw a line through the two points.

4 5 k 17 ¬11 4 5 k 17 17 ¬11 17 4 5 k ¬28 4 5 5 4 5 k ¬ 4 (28)

k ¬35 The solution set is {kk 35}.

Graphing Using Intercepts and Slope

y

1. 2x 3y 6 To find the x-intercept, let y 0. 2x 3y ¬6 2x 3(0) ¬6 2x ¬6 x ¬3 To find the y-intercept, let x 0. 2x 3y ¬6 2(0) 3y ¬6 3y ¬6 y ¬2 Put a point on the x-axis at 3 and a point on the y-axis at 2. Draw a line through the two points.

O (0, 3)

3y

6 (0, 2)

( 3, 0) O

(1, 0) 3x

y

x 3

4. x 2y 2 To find the x-intercept, let y 0. x 2y ¬2 x 2(0) ¬2 x ¬2 x ¬2 To find the y-intercept, let x 0. x 2y 2 0 2y 2 2y 2 y1

y 2x

(5, 0)

O

The solution set is ww 7 3 .

Page 741

10

(0, 2)

3 w 7 3 ¬ 3 w ¬7 3

24.

5y

x

485

Prerequisite Skills

Put a point on the x-axis at 2 and a point on the y-axis at 1. Draw a line through the two points.

7. y x 2 The y-intercept is 2. So, plot a point at (0, 2). The slope is 1. From (0, 2), move down 1 unit and right 1 unit. Plot a point. Draw a line connecting the points.

y x

2y

2

y ( 2, 0)

(0, 1)

x

O (1, 1)

(0, 2) O


x

y

8. y x 2 The y-intercept is 2. So, plot a point at (0, 2). The slope is 1. From (0, 2), move up 1 unit and right 1 unit. Plot a point. Draw a line connecting the points. y y

O (0, 2)

y 3x

4y

2

x

x

2

x (1, 1)

12

(0, 3)

9. y x 1 The y-intercept is 1. So, plot a point at (0, 1). The slope is 1. From (0, 1), move up 1 unit and right 1 unit. Plot a point. Draw a line connecting the points.

x O

(4, 0)

6. 4y x 4 To find the x-intercept, let y 0. 4y x ¬4 4(0) x ¬4 x ¬4 To find the y-intercept, let x 0. 4y x ¬4 4y 0 ¬4 4y ¬4 y ¬1 Put a point on the x-axis at 4 and a point on the y-axis at 1. Draw a line through the two points.

y y

(0, 1)

x

(1, 2)

O

x

10. y 3x 1 The y-intercept is 1. So, plot a point at (0, 1). The slope is 3. From (0, 1), move up 3 units and right 1 unit. Plot a point. Draw a line connecting the points.

y

(0, 1) 4y

1

x

y

4 x

O

(4, 0) y

3x

1

(1, 2) x

O (0, 1)

Prerequisite Skills

486

11. y 2x 3 The y-intercept is 3. So, plot a point at (0, 3). The slope is 2. From (0, 3), move down 2 units and right 1 unit. Plot a point. Draw a line connecting the points.

15. y 2x 2 To find the x-intercept, let y 0. y ¬2x 2 0 ¬2x 2 2x ¬2 x ¬1 To find the y-intercept, let x 0. y 2x 2 y 2(0) 2 y02 y 2 Put a point on the x-axis at 1 and a point on the y-axis at 2. Draw a line through the two points.

y 2x

y

(0, 3)

3

(1, 1) O

x

(2, 1)

y

12. y 3x 1 The y-intercept is 1. So, plot a point at (0, 1). The slope is 3. From (0, 1), move down 3 units and right 1 unit. Plot a point. Draw a line connecting the points.

2x

y

2

(1, 0)

O

x

(0, 2)

y

O

16. 6x y 2 To find the x-intercept, let y 0. 6x y ¬2 6x 0 ¬2 6x ¬2 x ¬1 3 To find the y-intercept, let x 0. 6x y ¬2 6(0) y ¬2 y ¬2 Put a point on the x-axis at 1 3 and a point on the y-axis at 2. Draw a line through the two points.

x y

(0, 1)

3x

1

(1, 4)

13. y 2 3x 3 The y-intercept is 3. So, plot a point at (0, 3). The slope is 2 3 . From (0, 3), move up 2 units and right 3 units. Plot a point. Draw a line connecting the points. y

y y

2– x 3

3

O

(0, 2) –1, 3

x (3, 1)

6x

y

2

0 O

x

(0, 3)

14. y 1 2x 1 The y-intercept is 1. So, plot a point at (0, 1). The slope is 1 2 . From (0, 1), move up 1 unit and right 2 units. Plot a point. Draw a line connecting the points.

17. 2y x 2 To find the x-intercept, let y 0. 2y x ¬2 2(0) x ¬2 x ¬2 x ¬2 To find the y-intercept, let x 0. 2y x ¬2 2y 0 ¬2 2y ¬2 y ¬1

y y

1– x 2

1

(2, 0) O

x (0, 1)

487

Prerequisite Skills

20. 4x y 4 To find the x-intercept, let y 0. 4x y ¬4 4x 0 ¬4 4x ¬4 x ¬1 To find the y-intercept, let x 0. 4x y ¬4 4(0) y ¬4 y ¬4 Put a point on the x-axis at 1 and a point on the y-axis at 4. Draw a line through the two points.

Put a point on the x-axis at 2 and a point on the y-axis at 1. Draw a line through the two points. y

(2, 0) O

x (0, 1)

2y

2

x


y

(0, 4)

x

21. y 2x 3 2

3 The y-intercept is 3 2 . So, plot a point at 0, 2 .

The slope is 2. From 0, 3 2 , move up 2 units and

right 1 unit. Plot a point. Draw a line connecting the points.

( 4, 0)

y

x

O

y

(0, 3) 4y

4

y

(1, 0)

O

y

3x

4x

2x

3– 2

1,–2 1

12 O 0,

19. 4x 3y 6 To find the x-intercept, let y 0. 4x 3y ¬6 4x 3(0) ¬6 4x ¬6 x ¬3 2 To find the y-intercept, let x 0. 4x 3y ¬6 4(0) 3y ¬6 3y ¬6 y ¬2 Put a point on the x-axis at 3 2 and a point on the y-axis at 2. Draw a line through the two points.

Pages 742–743 Solving Systems of Linear Equations 1.

4x

3y

6

–,3 0 2

y

y x 2 (2, 0) y

y

O

x –3 2

x

1 2x

1

x

The graphs appear to intersect at (2, 0). Check this estimate by replacing x with 2 and y with 0 in each equation. 1 Check: y ¬x 2 y ¬2x 1

(0, 2)

0 ¬2 2

1

0 ¬2(2) 1

0 ¬0 ✓ 0 ¬0 ✓ The system has one solution at (2, 0).

Prerequisite Skills

488

2.

6.

y

y

(2, 3)

yx1

x

(0, 1) x

y 3x 1

y 3x 3

The graphs appear to intersect at (2, 3). Check this estimate by replacing x with 2 and y with 3 in each equation. Check: y ¬3x 3 y ¬x 1 3 ¬3(2) 3 3 ¬2 1 3 ¬3 ✓ 3 ¬3 ✓ The system has one solution at (2, 3). 3.

The graphs appear to intersect at (0, 1). Check this estimate by replacing x with 0 and y with 1 in each equation. Check: 3y x ¬3 y 3x ¬1 3(1) 0 ¬3 1 3(0) ¬1 3 ¬3 ✓ 1 ¬1 ✓ The system has one solution at (0, 1). 7. Since x 2y 8, then x 8 2y. Substitute 8 2y for x in the first equation. 5x 3y ¬12 5(8 2y) 3y ¬12 40 10y 3y ¬12 40 13y ¬12 40 13y 40 ¬12 40 13y ¬52

y

y 2x 1 x

2y 4x 1

13y 52 ¬ 13 13

The graphs of the equations are parallel lines. Since they do not intersect, there are no solutions of this system of equations. 4.

y ¬4 Use x 8 2y to find the value of x. x ¬8 2y x ¬8 2(4) x ¬8 8 x ¬0 The solution is (0, 4). 8. Since x 4y 22, then x 4y 22. Substitute 4y 22 for x in the second equation. 2x 5y ¬21 2(4y 22) 5y ¬21 8y 44 5y ¬21 13y 44 ¬21 13y 44 44 ¬21 44 13y ¬65

y

6x 12y 6

x

2x 4y 2

The graphs of the equations are the same line. There are infinitely many solutions. 5.

3y x = 3

13y 5 6 ¬ 13 13

y

y ¬5 Use x 4y 22 to find the value of x. x 4y 22 x 4(5) 22 x 20 22 x2 The solution is (2, 5). 9. Since y 5x 3, then y 5x 3. Substitute 5x 3 for y in the second equation. 3y 2x ¬8 3(5x 3) 2x ¬8 15x 9 2x ¬8 17x 9 ¬8 17x 9 9 ¬8 9 17x ¬17

4x 3y 12 (3, 0) x

3x y 9

The graphs appear to intersect at (3, 0). Check this estimate by replacing x with 3 and y with 0 in each equation. Check: 4x 3y ¬12 3x y ¬9 4(3) 3(0) ¬12 3(3) 0 ¬9 12 ¬12 ✓ 9 ¬9 ✓ The system has one solution at (3, 0).

1 7x 17 17 ¬ 17

x ¬1

489

Prerequisite Skills

Use y 5x 3 to find the value of y. y 5x 3 y 5(1) 3 y53 y2 The solution is (1, 2). 10. Since y 2x 2, then y 2x 2. Substitute 2x 2 for y in the second equation. 7y 4x ¬23 7(2x 2) 4x ¬23 14x 14 4x ¬23 18x 14 ¬23 18x 14 14 ¬23 14 18x ¬9

Now substitute 3 for y in either equation to find the value of x. 3x 2y ¬2 3x 2(3) ¬2 3x 6 ¬2 3x 6 6 ¬2 6 3x ¬4 4 3 x 3 ¬ 3 x ¬4 3

The solution is (4 3 , 3). 14. Add the equations to eliminate y. 3x 4y ¬1 9x 4y ¬ 13 6x ¬ 12 6 x 12 ¬ 6 6 x ¬2 Now substitute 2 for x in either equation to find the value of y. 3y 4y ¬1 3(2) 4y ¬1 6 4y ¬1 6 4y 6 ¬1 6 4y ¬5

18 x 9 18 ¬ 18 x ¬1 2

Use y 2x 2 to find the value of y. y 2x 2 y 21 2 2 y12 y3 The solution is 1 2 , 3. 11. Since x 2y 5, then x 2y 5. Substitute 2y 5 for x in the first equation. 2x 3y ¬8 2(2y 5) 3y ¬8 4y 10 3y ¬8 y 10 ¬8 y 10 10 ¬8 10 y ¬2 Use x 2y 5 to find the value of x. x 2y 5 x 2(2) 5 x45 x 1 The solution is (1, 2). 12. Since 3x y 10, then y 3x 10. Substitute 3x 10 for y in the first equation. 4x 2y ¬5 4x 2(3x 10) ¬5 4x 6x 20 ¬5 10x 20 ¬5 10x 20 20 ¬5 20 10x ¬25

4y ¬5 4 4 y ¬5 4

The solution is 2, 5 4 . 15. Multiply the second equation by 2. Then add the equations to eliminate x. 4x 5y ¬11 4x 6y ¬22 11y ¬11 11y 11 ¬ 11 11

y ¬1 Now substitute 1 for y in either equation to find the value of x. 2x 3y ¬11 2x 3(1) ¬11 2x 3 ¬11 2x 3 3 ¬11 3 2x ¬8 2 x 8 2 ¬ 2 x ¬4 The solution is (4, 1). 16. Multiply the second equation by 3. Then add the equations to eliminate x. 6x 25y ¬21 6x 27y ¬21 22y ¬22

10 x 25 10 ¬ 10 5 x ¬2

Use y 3x 10 to find the value of y. y 3x 10 y 35 2 10 y 5 2

22y 22 ¬ 22 22

5 The solution is 5 2 , 2 .

y ¬1

13. Add the equations to eliminate x. 3x 2y ¬7 3x 2y ¬2 3y ¬9 3y ¬9 3 3

y ¬3

Prerequisite Skills

490

Use y 4x 11 to find the value of y. y 4x 11 y 4(3) 11 y 12 11 y1 The solution is (3, 1). 20. Solve by elimination. Multiply the first equation by 5 and the second equation by 2. Then add the equations. 20x 30y ¬ 15 20x 30y ¬8 0 ¬ 7 Since this is false, there is no solution.

Now substitute 1 for y in either equation to find the value of x. 6x 5y ¬1 6x 5(1) ¬1 6x 5 ¬1 6x 5 5 ¬1 5 6x ¬6 6 x 6 6 ¬ 6

x ¬1 The solution is (1, 1). 17. Multiply the first equation by 3 and the second equation by 2. Then add the equations to eliminate y. 9x 6y ¬24 10x 6y ¬32 x ¬38 Now substitute 8 for x in either equation to find the value of y. 3x 2y ¬8 3(8) 2y ¬8 24 2y ¬8 24 2y 24 ¬8 24 2y ¬16

21. Solve by graphing. y

(4, 3) 5x 5y 5 x

3x 2y 6

2y 1 6 ¬ 2 2

The graphs appear to intersect at (4, 3). Check this estimate by replacing x with 4 and y with 3 in each equation. Check: 3x 2y ¬6 5x 5y ¬5 3(4) 2(3) ¬6 5(4) 5(3) ¬5 12 6 ¬6 20 15 ¬5 6 ¬6 ✓ 5 ¬5 ✓ The system has one solution at (4, 3).

y ¬8 The solution is (8, 8). 18. Multiply the first equation by 3 and the second equation by 4. Then add the equations to eliminate x. 12x 21y ¬51 12x 28y ¬12 13y ¬39

22. Solve by elimination or substitution. Since 3y x 3, then x 3 3y. Substitute 3 3y for x in the second equation. 2y 5x ¬15 2y 5(3 3y) ¬15 2y 15 15y ¬15 15 17y ¬15 15 17y 15 ¬15 15 17y ¬0

13y 39 ¬ 1 13 3

y ¬3 Now substitute 3 for y in either equation to find the value of x. 4x 7y ¬17 4x 7(3) ¬17 4x 21 ¬17 4x 21 21 ¬17 21 4x ¬4 4 x 4 4 ¬ 4 x ¬1 The solution is (1, 3). 19. Solve by elimination or substitution. Since 4x y 11, then y 4x 11. Substitute 4x 11 for y in the second equation. 2x 3y ¬3 2x 3(4x 11) ¬3 2x 12x 33 ¬3 10x 33 ¬3 10x 33 33 ¬3 33 10x ¬30

17y 0 ¬ 17 17

y ¬0 Use x 3 3y to find the value of x. x 3 3y x 3 3(0) x30 x3 The solution is (3, 0). 23. Solve by elimination. Multiply the second equation by 2 and add the equations. 4x 7y ¬ 8 4x 10y ¬2 3y ¬ 6

1 0x 3 0 10 ¬ 10

3y ¬6 3 3

x ¬3

y ¬2

491

Prerequisite Skills

3y6 7. 98x ¬ 2 7 7 x3 y6

Substitute 2 for y in either equation to find the value of x. 4x 7y ¬8 4x 7(2) ¬8 4x 14 ¬8 4x 14 14 ¬8 14 4x ¬22

¬2 7 2 x3 y6 ¬2 7 x x y3 ¬7xy32x 2b 4c5 ¬ 4 c5 8. 56a 2 2 2 7 a2 b

¬2 2 14 a2 b 4 c5

4 x 22 4 ¬ 4 1 1 x ¬2 11 The solution is 2 ,2

¬2 14 a b2 c2 c ¬2ab2c214c

9.

24. Solve by elimination or substitution. Since x 3y 6, then x 6 3y. Substitute 6 3y for x in the second equation. 4x 2y ¬32 4(6 3y) 2y ¬32 24 12y 2y ¬32 24 14y ¬32 24 14y 24 ¬32 24 14y ¬56

¬9 7

10.

12 1 16 ¬ 1 6 1 21

11 ¬ 4

11.

63 8 ¬ 8

63

3 3 7

¬

2 2 2 37 ¬ 2 2 3 7 2 ¬ 2 2 2 14 3 ¬ 4

14y 5 6 ¬ 14 14

y ¬4 Use x 6 3y to find the value of x. x 6 3y x 6 3(4) x 6 12 x 6 The solution is (6, 4).

12.

288 28 8 147 ¬ 1 47

144 2 49 3 122 ¬ 73 122 3 ¬ 3 73 12 6 6 4 ¬ 7 3 or 7 2 10p p 1 0p3 13. ¬

27 9 3

¬

Pages 744–745 Square Roots and Simplifying Radicals 1. 32 ¬ 2 2 2 2 2 ¬ 42 2 ¬42 2. 75 ¬ 5 5 3 ¬5 2 3

p1 0p 3 3 3 p1 0p 3 ¬¬ 3 33 3 p30p ¬9

¬

¬53 3. 50 10 ¬ 50 10 ¬ 2 5 5 2 5 ¬ 22 5 2 5 ¬2 5 5

36 3 1 08 ¬ 14. 6 2 q6 q 2

¬105 4. 12 20 ¬ 12 20

¬ 3

6 3 q 2

¬ 2 2 3 2 25

2

2 ¬ 3

6 3 q 2

¬ 42 15 ¬415

6 or 6 3 6 ¬ 3 3

5. 6 6 ¬ 66

q 2

q

4 4 5 2 3 15. ¬ 5 2 3 5 23 5 2 3

¬36 or 6 6. 16 25 ¬ 16 25

45 23 2 ¬ 52 23

¬ 4 4 55 ¬4 2 5 2 ¬4 5 or 20

Prerequisite Skills

1 8 81 49 ¬ 4 9

20 83 ¬ 25 12 83 20 ¬ 13

492

5. (fg8)(15f 2g) (1)(15)(f f 2)(g8 g) 15(f 12)(g81) 15f 3g9 4 4 2 6. (6j k )(j k) (6)(1)(j4 j2)(k4 k) 6(j42)(k41) 6j6k5 3 2 7. (2ab )(4a b2) (2)(4)(a a2)(b3 b2) 8(a12)(b32) 8a3b5

7 3 7 3 5 26 16. ¬ 5 26

5 26

5 26

73 5 26 2 ¬ 52 26

3 35 1418 ¬

25 24 35 14 3 92 ¬ 1

¬353 422

3 2 3 3 2 3 8 8. 8 5 x y(4x y ) ¬ 5 (4)(x x )(y y )

3 3 17. ¬ 48 1 63 3 ¬ 43 3 3 ¬ 43 3 3 3 3 or ¬ 4 43

32 33)(y12) ¬ 5 (x 32 6 3 ¬ 5 x y

9. 2q2(q2 3) 2q2(q2) 2q2(3) 2q4 6q2 10. 5p(p 18) 5p(p) 5p(18) 5p2 90p 11. 15c(3c2 2c 5) 15c(3c2) 15c(2c) 15c(5) 45c3 30c2 75c 12. 8x(4x2 x 11) 8x(4x2) 8x(x) 8x(11) 32x3 8x2 88x 13. 4m2(2m2 7m 5) ¬4m2(2m2) 4m2(7m) 4m2(5) ¬8m4 28m3 20m2 14. 8y2(5y3 2y 1) 8y2(5y3) 8y2(2y) 8y2(1) 40y5 16y3 8y2

46 2 4 18. ¬ 125

25 5 26 ¬ 5 5 26 5 ¬ 5 5 5 30 2 ¬ 25

3 5 3 5 2 2 19. ¬ 2 2

2 2

2 2

35 2 2 ¬ 2 2 2 2

65 310 ¬

42 310 6 5 ¬ 2

16.

3 3 2 1 3 20. ¬ 2 13

2 13

17.

2 13

32 13 ¬ (2)2 13 2 6 313 ¬

18. 19.

4 13 32 13 ¬ 9

20.

2 13 ¬ 3

21.

Pages 746–747

Multiplying Polynomials

1. (3q2)(q5) (3)(1)(q2 q5) (3)(1)(q25) 3q7 2. (5m)(4m3) (5)(4)(m m3) (5)(4)(m13) 20m4

¬32 (m ) (n )

3 2 15. 3 2 m n

2

2

3 2

2 2

6 4 ¬9 4m n 3 2 2 (2c d ) (2)2(c3)2(d2)2 4c6d4 5 3 (5wx ) (5)3(w)3(x5)3 125w3x15 5 3 (6a b) 63(a5)3b3 216a15b3 2 3 (k ) (13k2)2 (k2)3(3)(132)(k2)2 k63(169)k4 169k6 k4 3 169k103 3 2 2 (5w x ) (2w5)2 (5)2(w3)2(x2)2(2)2(w5)2 25w6x4(4)w10 (25)(4)w6 w10 x4 100w16x4 3 2 2 4 (7y z )(4y ) (7)y3z2(4)4(y2)4 (7)y3z2(256)y8 (7)(256)y3 y8 z2 1792 y11z2

2 2 3 3 2 2 2 2 3 3 3 3 2 2 1 22. 1 2 p q (4pq ) ¬ 2 (p ) (q ) (4) (p) (q ) 3 9 4 4 ¬1 4 p q (64) p q 4 3 4 9 ¬1 4 64 p p q q

5 5 9 3. 9 2 c (8c ) ¬ 2 (8)(c c ) 15) ¬ 9 2 (8)(c

¬16p7q13 23. (m 1)(m 4) (m)(m) (m)(4) (1)(m) (1)(4) m2 4m m 4 m2 5m 4

¬36c6 4. (n6)(10n2) (1)(10)(n6 n2) 10(n62) 10n8

493

Prerequisite Skills

24. (s 7)(s 2) (s)(s) (s)(2) (7)(s) (7)(2) s2 2s 7s 14 s2 9s 14 25. (x 3)(x 4) (x)(x) (x)(4) (3)(x) (3)(4) x2 4x 3x 12 x2 x 12 26. (a 3)(a 6) (a)(a) (a)( 6) 3(a) (3)(6) a2 6a 3a 18 a2 3a 18 27. (5d 3)(d 4) (5d)(d) (5d)(4) (3)(d) (3)(4) 5d2 20d 3d 12 5d2 17d 12 28. (q 2)(3q 5) (q)(3q) (q)(5) (2)(3q) (2)(5) 3q2 5q 6q 10 3q2 11q 10 29. (2q 3)(5q 2) (2q)(5q) (2q)(2) (3)(5q) (3)(2) 10q2 4q 15q 6 10q2 19q 6 30. (2a 3)(2a 5) (2a)(2a) (2a)(5) (3)(2a) (3)(5) 4a2 10a 6a 15 4a2 16a 15 31. (d 1)(d 1) (d)2 (1)2 d2 1 32. (4a 3)(4a 3) (4a)2 (3)2 16a2 9 2 2 33. (s 5) (s) 2(s)(5) (5)2 s2 10s 25 2 34. (3f g) (3f )2 2(3f )(g) (g)2 9f 2 6fg g2 2 35. (2r 5) (2r)2 2(2r)(5) (5)2 4r2 20r 25

36. t 8 3

2

Pages 748–749 Dividing Polynomials 2 2

2

2

2

ac ¬ 2

q 5

5q5r3

3

¬5 r 2. q2 r2 q2r2 ¬5(q52)(r32) ¬5q3r

5 2 5 b2d ¬1 b d 3. 8 b 2 d3 8b2d3

2(2))(d53) ¬1 8 (b 2 b4d 4 2 ¬1 8 b d or 8 5p3x p3 ¬5 4. 2 p 7 x 2p7 3(7))x ¬5 2 (p 4 ¬5 2p x 3 4 2 4 3 s2 st 3r r s t 5. ¬3 2 r2 2r2st3 t 3 32)(s21)(t4(3)) ¬3 2 (r 5 1 7 ¬3 2r s t 3s t7 ¬ 2r5

3x3y1z5

y 3

1

5

¬3 x y z 6. x xyz2 z2

¬3(x31)(y11)(z52) ¬3x2y2z3 2 3

3x z ¬ 2 y

(w ) ¬ 3

4 3

4 3

w 7. 6

2

8.

1 6 64 ¬t2 3 t 9

37. (x 4)(x2 5x 2) x(x2 5x 2) 4(x2 5x 2) x3 5x2 2x 4x2 20x 8 x3 x2 22x 8 38. (x 2)(x2 3x 7) x(x2 3x 7) 2(x2 3x 7) x3 3x2 7x 2x2 6x 14 x3 x2 13x 14 39. (3b 2)(3b2 b 1) 3b(3b2 b 1) 2(3b2 b 1) 9b3 3b2 3b 6b2 2b 2 9b3 3b2 b 2 40. (2j 7)(j2 2j 4) 2j(j2 2j 4) 7(j2 2j 4) 2j3 4j2 8j 7j2 14j 28 2j3 3j2 6j 28

9.

10.

11.

12.

13.

Prerequisite Skills

2

21

8 ¬(t)2 2(t) 8 3 3

¬(a )c2

c a a c 1. 2a ¬ a 2

494

6 2 w1 ¬ 216 3q2 3 (3)3(q2)3 5 ¬ 53 27q6 ¬ 125 2 2 2y (2)2(y2)2 7 ¬ 72 4y4 ¬49 4 2 4 2)4 5m 5 (m ¬ 3 34 625m8 ¬8 1 2 16z 36 2 z 4z 4z 16 3 6 ¬ 4z 4z 4z 4z 9 ¬z 4 z 5d2 8 d 20 (5d2 8d 20) 10d ¬ 10d 2 5d 8d 20 ¬ 10d 10d 10d 4 2 ¬d 2 5 d p3 12p2 3p 8 (p3 12p2 3p 8) 4p ¬ 4p p3 12p2 3p 8 ¬ 4p 4p 4p 4p p2 2 ¬ 3p 3 4 p 4

b 4b 10 14. (b3 4b2 10) 2b ¬ 2b 3

2

b3

4b2

24.

10 ¬ 2b 2b 2b 2

¬b2 2b 5 b 3 2 6a 4a a3 6a2 4a 3 ¬a 3 15. 2 2 2 2 2

a

a 4 ¬a 6 a 32 a 8x2y 10xy2 8x2y 10xy2 6x3 16. ¬ 2x2 2x2 2x2 5y2 ¬4y 3x x s2 2s 8 (s 4)(s 2) 17. ¬ s4 s4 (s 4)(s 2) ¬ (s 4) a

a

a

6x3 2x2

Therefore, (d3 2d2 4d 24) (d 2) d2 4d 12. 25. 2j2 4j 13 j 2 2 j3 j 02 j 5 6 2 () 2j3 4j2 4j2 5j () 4j2 8j 13j 26 () 13j 26 0 Therefore, (2j3 5j 26) (j 2) 2j2 4j 13.

¬(s 2)

18.

(r2

r 9r 20 9r 20) (r 5) ¬ (r 5) 2

(r 5)(r 4) ¬ (r 5)

(r 5)(r 4) ¬ (r 5)

¬r 4 t2

4 2 x3 x 32 x 0 7 16

x 3 8x2 ().2x 11x2 0x () 11x2 44x 44x 176 () 44x 176 0

7t 12

(t 3)(t 4) ¬ (t 3) (t 3)(t 4) ¬ (t 3)

¬t 4

20.

c 3c 54 3c 54) (c 9) ¬ (c 9) 2

2x 3x 176 Therefore, 2x2 11x 44. x4 3

(c 9)(c 6) ¬ (c 9) (c 9)(c 6) ¬ (c 9) ¬c 6

27.

2q2 9q 5

21. (2q2 9q 5) (q 5) ¬ (q 5) (q 5)(2q 1)

¬ (q 5) (q 5)(2q 1)

¬ (q 5)

28.

¬2q 1 (z 1)(3z 5) 3z2 2z 5 22. ¬ z1 (z 1) (z 1)(3z 5)

¬ (z 1)

¬3z 5 23.

2x2 11x 44

26.

19. (t2 7t 12) (t 3) ¬ (t 3)

(c2

d2 4d 12 d 2 d 3 d 22 d 4 4 2 3 2d2 ().d 2 4d 4d () 4d2 8d 12d 24 () 12d 24 0

m2 4m 1 m 1 m 3 m 32 m 5 1 3 m2 ().m 2 4m 5m () 4m2 4m m 1 () m 1 0

2

x2 x 4 x2 x 6 3 2 4x (). x 2x 3 () 2x 8 11 11 Therefore, (x2 6x 3) (x 4) x 2 x 4. h2 4h 2 h 2 h 3 h 22 h 6 1 3 2h2 ().h 2 4h 6h () 4h2 8h 2h 1 () 2h 4 5

h3 2h2 6h 1 h2 4h 2 5 Therefore, h2 h2

Pages 750–751

Factoring to Solve Equations

1. Factor u2 12u. u2 u u, 12u 2 2 3 u GCF: u u2 12u u u u 12 u(u 12)

(m3 3m2 5m 1) Therefore, m2 4m 1. m1

495

Prerequisite Skills

2. Factor w2 4w. w2 w w, 4w 2 2 w GCF: w w2 4w w w w 4 w(w 4) 2 3. Factor 7j 28j. 7j2 7 j j, 28j 2 2 7 j GCF: 7 j or 7j 7j2 28j 7j j 7j 4 7j(j 4) 4. Factor 2g2 24g. 2g2 2 g g, 24g 2 2 2 3 g GCF: 2 g or 2g 2g2 24g 2g g 2g 12 2g(g 12) 5. Factor 6x2 2x. 6x2 2 3 x x, 2x 2 x GCF: 2 x or 2x 6x2 2x 2x 3x 2x 1 2x(3x 1) 6. Factor 5t2 30t. 5t2 5 t t, 30t 2 3 5 t GCF: 5 t or 5t 5t2 30t 5t t 5t 6 5t(t 6) 2 7. z 10z 21 In this equation, b is 10 and c is 21. Find two numbers with a product of 21 and with a sum of 10. Factors of 21

Sum of Factors

1, 21 3, 7

22 10

10. x2 14x 48 In this equation, b is 14 and c is 48. Find two numbers with a product of 48 and with a sum of 14.

Sum of Factors

1, 15 3, 5

16 18

Sum of Factors

1, 48 2, 24 3, 16 4, 12 6, 8

49 26 19 16 14

The correct factors are 6 and 8; m 6, n 8. x2 14x 48 (x m)(x n) (x 6)(x 8) 11. m2 6m 7 In this equation, b is 6 and c is 7. Find two numbers with a product of 7 and with a sum of 6. Factors of 7

Sum of Factors

1, 7

6

1, 7

6

The correct factors are 1 and 7; k 1, n 7. m2 6m 7 (m k)(m n) (m 1)(m 7) 12. b2 2b 24 In this equation, b is 2 and c is 24. Find two numbers with a product of 24 and with a sum of 2.

The correct factors are 7 and 3; m 7, n 3. z2 10z 21 (z m)(z n) (z 7)(z 3) 8. n2 8n 15 In this equation, b is 8 and c is 15. Find two numbers with a product of 15 and with a sum of 8. Factors of 15

Factors of 48

Factors of 24

Sum of Factors

1, 24

23

1, 24

23

2, 12

10

2, 12

10

3, 8

5

3, 8

15

4, 6

2

4, 6

12

The correct factors are 4 and 6; m 4, n 6. b2 2b 24 (b m)(b n) (b 4)(b 6) 13. q2 9q 18 In this equation, b is 9 and c is 18. This means that m n is negative and mn is positive. So, m and n must both be negative.

The correct factors are 3 and 5; m 3, p 5. n2 8n 15 (n m)(n p) (n 3)(n 5) 9. h2 8h 12 In this equation, b is 8 and c is 12. Find two numbers with a product of 12 and with a sum of 8.

Factors of 18

Sum of Factors

1, 18

19

Factors of 12

Sum of Factors

2, 9

11

1, 12 2, 6 3, 4

13 8 7

3, 6

19

The correct factors are 3 and 6; m 3, n 6. q2 9q 18 (q m)(q n) (q 3)(q 6)

The correct factors are 2 and 6; m 2, n 6. h2 8h 12 (h m)(h n) (h 2)(h 6)

Prerequisite Skills

496

14. p2 5p 6 In this equation, b is 5 and c is 6. This means that m n is negative and mn is positive. So, m and n must both be negative.

18. y2 3y 88 In this equation, b is 3 and c is 88. Find two numbers with a product of 88 and with a sum of 3.

Factors of 6

Sum of Factors

Factors of 88

Sum of Factors

1, 6

7

1, 88

87

2, 3

5

1, 88

87

2, 44

42

2, 44

42

4, 22

18

4, 22

18

8, 11

3

8, 11

13

The correct factors are 2 and 3; m 2, n 3. p2 5p 6 (p m)(p n) (p 2)(p 3) 15. a2 3a 4 In this equation, b is 3 and c is 4. Find two numbers with a product of 4 and with a sum of 3. Factors of 4

Sum of Factors

1, 4

3

1, 4 2, 2

3 0

The correct factors are 11 and 8; m 11, n 8. y2 3y 88 (y m)(y n) (y 11)(y 8) 19. 3z2 4z 4 In this equation, a is 3, b is 4, and c is 4. Find two numbers with a product of 12 and with a sum of 4.

The correct factors are 4 and 1; m 4, n 1. a2 3a 4 (a m)(a n) (a 4)(a 1) 16. k2 4k 32 In this equation, b is 4 and c is 32. Find two numbers with a product of 32 and with a sum of 4.

Factors of 12

Sum of Factors

1, 12

11

1, 12

11

Factors of 32

Sum of Factors

2, 6

4

1, 32

31

2, 6

14

1, 32

31

3, 4

11

2, 16

14

3, 4

11

2, 16

14

4, 8

4

4, 8

14

The correct factors are 2 and 6; m 2, n 6. 3z2 4z 4 3z2 mz nz 4 3z2 (2)z 6z 4 (3z2 2z) (6z 4) z(3z 2) 2(3z 2) (3z 2)(z 2) 20. 2y2 9y 5 In this equation, a is 2, b is 9, and c is 5. Find two numbers with a product of 10 and with a sum of 9.

The correct factors are 8 and 4; m 8, n 4. k2 4k 32 (k m)(k n) (k 8)(k 4) 17. n2 7n 44 In this equation, b is 7 and c is 44. Find two numbers with a product of 44 and with a sum of 7.

Factors of 10

Sum of Factors

Factors of 44

Sum of Factors

1, 10

9

1, 44

43

9

1, 44

1, 10

43

2, 5

3

2, 22

20

2, 5

3

2, 22

20

4, 11

7

4, 11

17

The correct factors are 1 and 10; m 1, n 10. 2y2 9y 5 2y2 my ny 5 2y2 (1)y 10y 5 (2y2 y) (10y 5) y(2y 1) 5(2y 1) (2y 1)(y 5)

The correct factors are 11 and 4; m 11, p 4. n2 7n 44 (n m)(n p) (n 11)(n 4)

497

Prerequisite Skills

The correct factors are 1 and 16; m 1, n 16. 8a2 15a 2 8a2 ma na 2 8a2 (1)a 16a 2 (8a2 a) (16a 2) a(8a 1) 2(8a 1) (8a 1)(a 2)

21. 5x2 7x 2 In this equation, a is 5, b is 7, and c is 2. Find two numbers with a product of 10 and with a sum of 7. Factors of 10

Sum of Factors

1, 10 2, 5

11 17

3 ¬w 3 2 w 2

2 3 25. w2 9 4 ¬w 2

The correct factors are 2 and 5; m 2, n 5. 5x2 7x 2 5x2 mx nx 2 5x2 2x 5x 2 (5x2 2x) (5x 2) x(5x 2) 1(5x 2) (5x 2)(x 1) 2 22. 3s 11s 4 In this equation a is 3, b is 11, and c is 4. Find two numbers with a product of 12 and with a sum of 11. Factors of 12

Sum of Factors

1, 12

11

1, 12

11

2, 6

4

2, 6

14

3, 4

11

3, 4

11

26. c2 64 c2 82 (c 8)(c 8) 27. r2 14r 49 r2 2(1r)(7) 72 (r 7)2 2 28. b 18b 81 b2 2(1b)(9) 92 (b 9)2 2 29. j 12j 36 j2 2(1j)(6) 62 ( j 6)2 2 30. 4t 25 (2t)2 52 (2t 5)(2t 5) 31. 10r2 35r 0 5r(2r 7) 0 5r 0 or 2r 7 0 r0 r 7 2 32. 3x2 15x 0 3x(x 5) 0 3x 0 or x 5 0 x0 x 5 33. k2 13k 36 0 (k 4)(k 9) 0 k 4 0 or k 9 0 k 4 k 9 34. w2 8w 12 0 (w 2)(w 6) 0 w 2 0 or w 6 0 w2 w6 35. c2 5c 14 0 (c 2)(c 7) 0 c 2 0 or c 7 0 c 2 c7 36. z2 z 42 0 (z 6)(z 7) 0 z 6 0 or z 7 0 z 6 z7 37. 2y2 5y 12 0 (2y 3)(y 4) 0 2y 3 0 or y 4 0 y 3 y4 2 2 38. 3b 4b 15 0 (3b 5)(b 3) 0 3b 5 0 or b 3 0 b 5 b3 3 2 39. t 12t 36 ¬0 (t 6)2 ¬0 t 6 ¬0 t ¬6

The correct factors are 1 and 12; m 1, n 12. 3s2 11s 4 3s2 ms ns 4 3s2 (1)s 12s 4 (3s2 s) (12s 4) s(3s 1) 4(3s 1) (3s 1)(s 4) 23. 6r2 5r 1 In this equation, a is 6, b is 5, and c is 1. Find two numbers with a product of 6 and with a sum of 5. Note that m and n are both negative. Factors of 6

Sum of Factors

1, 6

7

2, 3

5

The correct factors are 2 and 3; m 2, n 3. 6r2 5r 1 6r2 mr nr 1 6r2 (2)r (3)r 1 (6r2 2r) (3r 1) 2r(3r 1) 1(3r 1) (2r 1)(3r 1) 24. 8a2 15a 2 In this equation, a is 8, b is 15, and c is 2. Find two numbers with a product of 16 and with a sum of 15. Factors of 16

Sum of Factors

1, 16

15

1, 16

15

2, 8

6

2, 8

1 6

4, 4

10

Prerequisite Skills

2

498

25 40. u2 5u 4 ¬0

u 5 2

2

4. C B

¬0

u 5 2 ¬0 u ¬5 2 2 41. q 8q 16 ¬0 (q 4)2 ¬0 q 4 ¬0 q ¬4 42. a2 6a 9 ¬0 (a 3)2 ¬0 a 3 ¬0 a ¬3

2. B C

1 8 3 0 2 (2) 8 2 7 (10) 6 6

1 3 2 8 7 6

7. 4C 4

7 3 0 10 3 12

5 15 10 40 35 30

8 0 10 9 3. A C 4 3 2 2 1 11 10 6

5(1) 5(3) 5(2) 5(8) 5(7) 5(6)

1 3 8 0 2 8 2 2 7 6 10 6

10 8 9 0 4 (2) 3 2 1 (10) 11 6

2 9 6 5 9 5

8 0 2 2 10 6

4(8) 4(0) 4(2) 4(2) 4(10) 4(6)

1 8. 1 2C 2

30 27 12 9 3 33

6. 5B 5

9 12 5 6 6 17

9 3 4 6 17 0

3(10) 3(9) 3(4) 3(3) 3(1) 3(11)

10 (1) 9 (3) 3 8 42 11 6 1 7

8 (1) 0 (3) 28 2 2 66 10 7

1 3 10 9 2 8 1. A B 4 3 7 6 1 11

10 9 4 3 1 11

5. 3A 3

Pages 752–753 Operations with Matrices

8 0 1 3 2 8 2 2 7 6 10 6

0 32 8 8 40 24 8 0 2 2 10 6

1(8) 1 2 (0) 2 1 1 (2) 2(2) 2 1 (10) 1 2 (6) 2

4 0 1 1 5 3

499

Prerequisite Skills

10. A 5C

12. 3A 3B 3

3(10) 3(9) 3(4) 3(3) 3(1) 3(11)

8 0 20 18 8 6 2 2 2 22 10 6

30 27 12 9 3 33

20 8 18 0 8 (2) 6 2 2 (10) 22 6

30 (3) 27 (9) 12 6 9 24 33 18 3 21

33 18 6 33 24 15

28 18 6 4 12 28

8 0 10 9 4 3 5 2 2 1 11 10 6

13. X Z

10 9 4 3 1 11

40 10 50

0 10 30

30 9 14 13 49 19

4 0 1 1 5 3

1(8) 1(0) 2 2 1(2) 1(2) 2 2 1(10) 1(6) 2 2

1 3 2 8 7 6

63

16 4

16

0 4 8 5 7 0

4 6 1 (7)

13 8 5

102 84 16

500

0 5

8 0 2 10(1) 6 4 (5)

34 89

3(1) 3(6)

3 18

0 5

3(0) 3(5)

0 15

102 84

4 (1) 0 (3) 18 1 2 36 5 7

0 (8) 5 0

17. 6X 6

3 3 1 9 2 9

Prerequisite Skills

16

102 84 74 80

16. 3Y 3

1 3 2 8 7 6

3 9 6 24 21 18

4 8 (8) 10 2(7) 4 0

15. X Y

8 0 1 3 C B 1 2 2 2 8 11. 1 2 2 7 6 10 6

3(1) 3(3) 3(2) 3(8) 3(7) 3(6)

14. Y Z

10 40 9 0 4 (10) 3 10 1 (50) 11 30

1 3 10 9 4 3 3 2 8 7 6 1 11

8 0 2(10) 2(9) 2(4) 2(3) 2 2 2(1) 2(11) 10 6

5(8) 5(0) 10 9 4 3 5(2) 5(2) 5(10) 5(6) 1 11

10 9 8 0 4 3 2 2 1 11 10 6

9. 2A C 2

6(2) 6(8) 6(10) 6(4)

12 60

48 24

2 8 4 8 1 18. 1 2 X Z 2 10 4 0 7

102 84 74 80 2(4) (8)(7) 2(8) (8)(0) 10(4) 4(7) 10(8) 4(0)

1(2) 1 2 (8) 2 1(4) 1(10) 2 2

22. XZ

74 80

15 42 74

4 4 (8) 5 1(7) 2 0

25 122

16 64 12 80 2 8 4 8 1 23. 1 2 (XZ) 2 10 4 7 0 2(4) (8)(7) 2(8) (8)(0) 1 2 10(4) 4(7) 10(8) 4(0) 64 16 1 2 12 80

8 0

74 80 216 50 5(4) 5(8) 2(1) 2(0) 5(7) 5(0) 2(6) 2(5) 20 40 2 0 35 0 12 10 20 (2) 40 0 35 12 0 (10) 22 40 47 10 2 8 1 0 20. XY 10 4 6 5 2(1) (8)(6) 2(0) (8)(5) 10(1) 4(6) 10(0) (4)(5) 50 40 14 20 19. 5Z 2Y 5

1(64) 1(16) 2 2 1(12) 1(80) 2 2

8 326 40

24. XY 2Z

102 84 16

4 8 0 2 5 7 0

(8)(6) 2(1) 10(1) 4(6)

2(4) 2(7)

2(0) (8)(5) 10(0) (4)(5)

2(8) 2(0)

40 8 16 50 14 20 14 0 50 8 40 (16) 14 (14) 20 0 42 24 0 20

16 50 74 80 (1)(4) 0(7) (1)(8) 0(0) 6(4) (5)(7) 6(8) (5)(0) 8 4 59 48

21. YZ

501

Prerequisite Skills

Extra Practice Page 754

8.

Lesson 1-1

1. There are 8 planes: plane ABD, plane GLJ, plane AFL, plane FEK, plane EDJ, plane DCI, plane CBH, and plane ABH. 2. B, O, and C or D, M, and J 3. planes AFG, ABG, and GLK 4. DE 5. Sample answer: planes ABD and GHJ 6. plane FEK 7. A line; two planes intersect in a line, not a point. 8.

32 3m

17

A B AC ¬AB BC 32 ¬17 3m 15 ¬3m 5 ¬m BC ¬3m BC ¬3(5) BC ¬15 9.

X

Y

A

Z

B

9a

C

B

b

m Page 754

Lesson 1-2

1. The measurement is precise to within 1 2 in. So, a measurement of 42 in. could be 41 1 2

2.

3.

4.

5.

10.

B C AC ¬AB BC 7b 13 ¬25 3b 7b 13 13 ¬25 3b 13 7b ¬12 3b 7b 3b ¬12 3b 3b 4b ¬12 4b 1 2 4 ¬ 4 b ¬3 BC 3b BC 3(3) BC 9

6. The measurement is precise to within 0.5 m. So, a measurement of 89 m could be 88.5 to 89.5 m. 7.

Extra Practice

3b

A

1 3 So, a measurement of 5 1 4 ft could be 5 8 to 5 8 ft.

A B AB 4x ¬16 4 x 16 4 ¬ 4 x ¬4 BC 5x BC 5(4) BC 20

C

7b 13 25

to 42 1 2 in. The measurement is precise to within 0.5 mm. So, a measurement of 86 mm could be 85.5 to 86.5 mm. The measurement is precise to within 0.5 cm. So, a measurement of 251 cm could be 250.5 to 251.5 cm. The measurement is precise to within 0.05 in. So, a measurement of 33.5 in. could be 33.45 to 33.55 in. The measurement is precise to within 1 8 ft.

4x 16

12a

A B AC ¬AB BC 42 ¬9a 12a 42 ¬21a 42 21 a 21 ¬ 21 2 ¬a BC ¬12a BC ¬12(2) BC ¬24

Z A

42

a

9.

X

C

11.

54 5n 5

5x

A

2n

B AC ¬AB BC 54 ¬5n 5 2n 54 ¬7n 5 54 5 ¬7n 5 5 49 ¬7n 4 9 7n 7 ¬ 7 7 ¬n BC ¬2n BC ¬2(7) BC ¬14

C

502

C

12.

4.

65 6c 8

y

O

6

3c 1

2

A

B C AC ¬AB BC 65 ¬6c 8 3c 1 65 ¬9c 7 65 7 ¬9c 7 7 72 ¬9c 7 c 2 9 9 ¬ 9 8 ¬c BC ¬3c 1 BC ¬3(8) 1 BC ¬25

6 2

2 2

6

x

6

M X (MO)2 ¬(MX)2 (OX)2 (MO)2 ¬(8)2 (15)2 (MO)2 ¬289 MO ¬17 5.

y 6

Page 754 1.

Lesson 1-3

T

O 2

y

B

2 2

x

6

6

X

A

x

X R (TR)2 ¬(TX)2 (RX)2 (TR)2 ¬(16)2 (12)2 (TR)2 ¬400 TR ¬20

(AB)2 ¬(AX)2 (BX)2 (AB)2 ¬(3)2 (4)2 (AB)2 ¬25 AB ¬5 2.

y

6.

y

N

N 6

6 2 O 2

6

x

4

X

(FN)2 ¬(FX)2 (NX)2 (FN)2 ¬(10)2 (12)2 (FN)2 ¬244 FN ¬ 244 FN ¬15.6

C X O

x

(CN)2 ¬(CX)2 (NX)2 (CN)2 ¬(6)2 (8)2 (CN)2 ¬100 CN ¬10 3.

7.

2 (7) DM ¬8 2 DM ¬ 64 49 DM ¬ 113 DM ¬10.6

6

6

O2

X

4

d ¬(x x1)2 (y2 y1)2 2 2 ( DM ¬ (8 0) 7 0)2

y

2

F

Z 8.

x

d ¬ (x2 x1)2 (y2 y1)2 2 XY ¬ [1 (1)] (1 1)2

Y

XY ¬ 22 ( 2)2 XY ¬ 44 XY ¬ 8 XY ¬2.8

8

(XZ)2 ¬(XY)2 (ZY)2 (XZ)2 ¬(12)2 (5)2 (XZ)2 ¬169 XZ ¬13

503

Extra Practice

d ¬ (x2 x1)2 (y2 y1)2

9.

ZA ¬ [3 (4)]2 (7 0)2

x1 0 5 ¬ 2

ZA ¬ 12 72 ZA ¬ 1 49 ZA ¬ 50 ZA ¬7.1

(7) y (4) 2 2 x1 (7) y1 (4) 3 ¬ 5 ¬ 2 2

6)2

x 2 8

x1 8 10 ¬ 2

2 (1) TN ¬1 2 TN ¬ 11 TN ¬ 2 TN ¬1.4

x 2 6

x1 6 3 ¬ 2

SE ¬

y 8 2

1 5 ¬

6 ¬x1 6 10 ¬y1 8 12 ¬x1 2 ¬y1 The coordinates of A are (12, 2).

SE ¬(13) 2 (5)2 SE ¬ 169 25 SE ¬ 194 SE ¬13.9

x 2 6

y (8) 2 y1 (8) 4 ¬ 2

1 1 23. B(3, 4) ,

x1 6 3 2

6 x1 6 8 ¬y1 (8) 0 x1 0 ¬y1 The coordinates of A are (0, 0).

¬(1, 4) x1 x2 y1 y2 4 2 3 2 14. , ¬2, 2 2 2 2 1 ¬ 2 , 2

(2) y (4) 2 2 x1 (2) y1 (4) 0 5 ¬ 2 2

x

1 1 24. B(0, 5) ,

¬(1, 0.5)

0 x1 (2) 10 ¬y1 (4) 2 x1 14 ¬y1 The coordinates of A are (2, 14).

x1 x2 y1 y2 4 5 5 4 15. , ¬2, 2 2 2 1 ¬1 2, 2

y 8 2

1 1 22. B(3, 5) ,

d ¬

20 ¬x1 8 4 ¬y1 (4) 28 ¬x1 8 ¬y1 The coordinates of A are (28, 8).

(x2 x1)2 (y2 y1)2 (6 7)2 (7 2)2

y (4) 2 y1 (4) 2 ¬ 2

1 1 21. B(10, 2) ,

TN ¬ [0 ( 1)]2 (2 3)2

x1 x2 y1 y2 0 (2) 0 (8) 13. , ¬ 2, 2 2 2 2 8 ¬ 2 , 2

6 ¬x1 (7) 10 ¬y1 (4) 14 ¬y1 13 ¬x1 The coordinates of A are (13, 14).

d ¬ (x2 x1)2 (y2 y1)2

y 0 2

1 6 ¬

x

KD ¬ (9)2 (9)2 KD ¬ 81 81 KD ¬ 162 KD ¬12.7

12.

1 1 20. B(3, 5) ,

KD ¬ (3 (3 6)2

11.

y 0 2

10 ¬x1 0 12 ¬y1 0 10 ¬x1 12 ¬y1 The coordinates of A are (10, 12).

d ¬ (x2 x1)2 (y2 y1)2

10.

x 2 0

1 1 19. B(5, 6) ,

¬(0.5, 0.5)

Page 755

x1 x2 y1 y2 10 8 5 4 16. , ¬2, 2 2 2 2 9 ¬ 2 , 2

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.

¬(1, 4.5) x1 x2 y1 y2 2.8 1.2 3.4 5.6 17. , ¬2, 2 2 2 2.2 ¬4 2, 2

¬(2, 1.1) x1 x2 y1 y2 6.2 3.4 7 (4.8) 18. , ¬2, 2 2 2 2 .8 2.2 ¬ 2 , 2

¬(1.4, 1.1)

Extra Practice

504

Lesson 1-4

B E G I IA, IE ED, EF GC, GH , HF HA DCG 4 BCG 120°; 120 90 and 120 180 so ABC is obtuse. 90°; CGF is a right angle. 60°; 60 90 so HIF is acute.

Page 755

Lesson 1-5

Page 755

1. Sample answer: BGC and FGE are vertical angles. They each have measures less than 90, so they are acute. 2. Sample answer: BGF and CGE are vertical angles. They each have measures greater than 90, so they are obtuse. 3. Sample answer: BED is a right angle, so BEC and CED are adjacent angles that are complementary because mBEC mCED mBED. 4. Sample answer: CEF and CED are adjacent angles that are supplementary because they form a linear pair. 5. Sample answer: ABE is a right angle and CBE is adjacent to and forms a linear pair with ABE, so CBE is also a right angle. 6. BGC and FGE are vertical angles. mBGC ¬mFGE 4x 5 ¬6x 15 5 ¬2x 15 20 ¬2x 10 ¬x BGF and FGE form a linear pair, so mBGF mFGE ¬180. mBGF mFGE ¬180 mBGF 6x 15 ¬180 mBGF 6(10) 15 ¬180 mBGF 45 ¬180 mBGF ¬135 7. A C C D if BCD is a right angle, so mBCD 90. mBCD ¬mBCG mGCE mECD 90 ¬5a 5 3a 4 4a 7 90 ¬12a 6 96 ¬12a 8 ¬a 8. A and B form a linear pair, so mA mB 180. We are given that mA mB 9. mA mB ¬180 mB 9 mB ¬180 2(mB) ¬189 mB ¬94.5 mA ¬mB 9 ¬94.5 9 ¬85.5 9. Let x represent the measure of the angle. Then its complement has measure x 17. x x 17 ¬90 2x 17 ¬90 2x ¬73 x ¬36.5 x 17 ¬53.5 The angle has measure 36.5, and its complement has measure 53.5.

Lesson 1-6

1. There are 4 sides, so the polygon is a quadrilateral. No line containing any of the sides will pass through the interior of the quadrilateral, so it is convex. The sides are congruent, and the angles are congruent, so it is regular. Its perimeter is 22.5 m 22.5 m 22.5 m 22.5 m, or 90 m. 2. There are 6 sides, so the polygon is a hexagon. There is a side such that a line containing that side will pass through the interior of the hexagon, so it is concave. The sides are not congruent, so it is irregular. Its perimeter is 25 cm 25 cm 25 cm 25 cm 28 cm 28 cm, or 156 cm. 3. There are 16 sides, so the polygon is a 16-gon. There is a side such that a line containing that side will pass through the interior of the polygon, so it is concave. The sides are not congruent, so it is irregular. Its perimeter is 24 12 12 48 12 12 24 12 12 12 12 24 12 12 12 12 or 264 in. 4.

d ¬ (x2 x1)2 (y2 y1)2 XY ¬ (2 3)2 (1 3)2 2 ¬(5) (2)2 ¬29 YZ ¬ [1 ( 2)]2 (3 1)2 2 2 ¬3 (4) ¬ 25 or 5 XZ ¬ (1 3 )2 ( 3 3 )2 2 ¬(2) (6)2 ¬ 40 The perimeter is XY YZ XZ 29 5 40 16.7 units.

5.

2 d ¬ (x2 x (y2 y1)2 1)

PE ¬ [5 (2)]2 (0 3)2 2 ¬(3) (3)2 ¬18 EN ¬ [2 (5)]2 ( 4 0 )2 2 2 ¬3 (4) ¬ 25 or 5 2 NT ¬ [2 (2)] [1 ( 4)]2 2 2 ¬4 3 ¬ 25 or 5 TA ¬ (2 2 )2 [2 ( 1)]2 2 2 ¬0 3 ¬ 9 or 3 2 PA ¬ [2 (2)] (2 3)2 2 (1) ¬4 2 ¬ 17 The perimeter is PE EN NT TA PA 18 5 5 3 17 21.4 units.

505

Extra Practice

is an angle bisector of TSU. 4. Given: SR

2 d ¬ (x2 x (y2 y1)2 1)

6.

HE ¬ (3 0)2 (2 4) 2

T

2 ¬(3) (2)2 ¬13 EX ¬ [3 (3)]2 ( 2 2 )2 2 2 ¬0 (4) ¬ 16 or 4 XG ¬ [0 ( 3)]2 [5 ( 2)]2 2 2 ¬3 (3) ¬ 18 GO ¬ (5 0 )2 [ 2 ( 5)]2 2 2 ¬5 3 ¬ 34 ON ¬ (5 5 )2 [2 ( 2)]2 2 42 ¬0 ¬ 16 or 4 HN ¬ (5 0 )2 (2 4)2 2 2 ¬5 (2) ¬ 29 The perimeter is HE EX XG GO ON HN 13 4 18 34 4 29 27.1 units.

Page 756

R S

5.

6.

7. 8.

U TSR and RSU have equal measures, by definition of bisector. Conjecture: TSR RSU EF and FG are side lengths of equilateral triangle EFG. By definition, the three side lengths of any equilateral triangle are equal. The conjecture is true. Some rational numbers are not whole numbers. For example, r 0.5 is a rational number but not a whole number. So the conjecture is false. Every whole number n is a rational number of the form n 1. The conjecture is true. Two angles can be supplementary without being a linear pair. The angles shown have measures that sum to 180, but they are not adjacent with opposite rays as their noncommon sides. 70 110

Lesson 2-1

1. Given: Lines j and k are parallel.

The conjecture is false.

j Page 756

k Since parallel lines by definition never intersect, lines j and k cannot intersect. Conjecture: Lines j and k do not intersect. 2. Given: points A(1, 7), B(4, 7), C(4, 3), D(1, 3) y O

x

D ( 1, 3)

C (4, 3)

B (4, 7)

A ( 1, 7)

B and C D are horizontal, while Line segments A line segments B C and A D are vertical. Conjecture: ABCD is a rectangle 3. Given: A B bisects C D at K. B

C

K

D

A K is the midpoint of C D , by definition of bisect. Conjecture: CK KD Extra Practice

Lesson 2-2

1. (3)2 9 and a robin is a fish. p and q is false, because p is true and q is false. 2. (3)2 9 or a robin is a fish. p or q is true because p is true. It does not matter that q is false. 3. (3)2 9 and an acute angle measures less than 90°. p and r is true, because p is true and r is true. 4. (3)2 9 or an acute angle measures less than 90°. p or r is true, because p is true and r is true. 5. (3)2 9 or a robin is a fish. p or q is false, because p is false and q is false. 6. (3)2 9 or an acute measures 90° or more. p or r is true, because p is true. It does not matter that r is false. 7. A robin is a fish and an acute angle measures less than 90°. q r is false because q is false and r is true. 8. (3)2 9 and a robin is a fish, or an acute angle measures less than 90°. (p q) r true because r is true. It does not matter whether p q is true or false. 9. (3)2 9 or an acute angle measures 90° or more. p r is false, because p is false and r is false.

506

10.

11.

p

q

q

p q

T

T

F

T

T

F

T

T

F

T

F

F

F

F

T

T

p

q

p

q

p q

T

T

F

F

F

T

F

F

T

T

F

T

T

F

T

F

F

T

T

T

Page 756 1.

Converse: If a figure is a polygon, then it is a triangle. The converse is false. A pentagon is a polygon but is not a triangle. Inverse: If a figure is not a triangle, then it is not a polygon. The inverse is false. A hexagon is not a triangle, but it is a polygon. The contrapositive is the negation of the hypothesis and conclusion of the converse. Contrapositive: If a figure is not a polygon, then it is not a triangle. The contrapositive is true. 10. Conditional: If two angles are congruent angles, then they have the same measure. The conditional statement is true. Write the converse by switching the hypothesis and conclusion of the conditional. Converse: If two angles have the same measure, then they are congruent angles. The converse is true. Inverse: If two angles are not congruent angles, then they do not have the same measure. The inverse is true. The contrapositive is the negation of the hypothesis and conclusion of the converse. Contrapositive: If two angles do not have the same measure, then they are not congruent angles. The contrapositive is true. 11. Conditional: If three points lie on the same line, then they are collinear. The conditional statement is true. Write the converse by switching the hypothesis and conclusion of the conditional. Converse: If three points are collinear, then they lie on the same line. The converse is true. Inverse: If three points do not lie on the same line, then they are not collinear. The inverse is true. The contrapositive is the negation of the hypothesis and conclusion of the converse. Contrapositive: If three points are not collinear, then they do not lie on the same line. The contrapositive is true. 12. Conditional: If PQ is a perpendicular bisector of M L , then a right angle is formed. The conditional statement is true. Write the converse by switching the hypothesis and conclusion of the conditional. and Converse: If a right angle is formed by PQ is a perpendicular bisector of L M L , then PQ M . The converse is false. PQ may not pass through the midpoint of L M . Inverse: If PQ is not a perpendicular bisector of M L , then a right angle is not formed. The inverse could be perpendicular to L is false. PQ M without bisecting L M . The contrapositive is the negation of the hypothesis and conclusion of the converse. Contrapositive: If a right angle is not formed by and L is not a perpendicular PQ M , then PQ bisector of L M . The contrapositive is true.

Lesson 2-3

If no sides of a triangle are equal, then it is a scalene triangle. hypothesis

conclusion

Hypothesis: no sides of a triangle are equal Conclusion: it is a scalene triangle 2.

If it rains today, you will be wearing your raincoat. hypothesis

conclusion

Hypothesis: it rains today Conclusion: you will be wearing your raincoat 3.

If 6

x

11, then x

5.

hypothesis conclusion

Hypothesis: 6 x 11 Conclusion: x 5 4.

If you are in college, you are at least 18 years old. hypothesis

5.

6.

7.

8.

9.

conclusion

Hypothesis: you are in college Conclusion: you are at least 18 years old The sum of the measures of two supplementary angles is 180. Hypothesis: two angles are supplementary Conclusion: the sum of their measures is 180 If two angles are supplementary, then the sum of their measures is 180. A triangle with two congruent sides is an isosceles triangle. Hypothesis: a triangle has two congruent sides Conclusion: it is an isosceles triangle If a triangle has two congruent sides, then it is an isosceles triangle. Two lines that do not intersect are parallel lines. Hypothesis: two lines do not intersect Conclusion: they are parallel If two lines do not intersect, then they are parallel. A Saint Bernard is a dog. Hypothesis: an animal is a Saint Bernard Conclusion: it is a dog If an animal is a Saint Bernard, then it is a dog. Write the conditional in if-then form. Conditional: If a figure is a triangle, then it is a polygon. The conditional statement is true. Write the converse by switching the hypothesis and conclusion of the conditional.

507

Extra Practice

Page 757

5x 1 4. Given: 3 8 Prove: x 5 Proof:

Lesson 2-4

1. (1) If it rains, then the field will be muddy. (2) If the field is muddy, then the game will be cancelled. Let p, q, and r represent the parts of the statement. p: it rains q: the field will be muddy r: the game will be cancelled Statement (1): p → q Statement (2): q → r Since the given statements are true, use the Law of Syllogism to conclude p → r. That is, if it rains, then the game will be cancelled. 2. There is no valid conclusion. Although both statements may be true, the conclusion of one statement is not used as the hypothesis of the other. 3. p: it is snowing outside q: you will wear your winter coat. Statement (3) is a valid conclusion by the Law of Detachment. 4. Statement (1) is true, but statement (3) does not follow from statement (2). Not all pairs of acute angles are complementary. Statement (3) is invalid.

Page 757

Reasons

5x 1 a. 8 3

a.

b.

?

5x 1 8 8(3) b. Mult. Prop. 8

?

Substitution

d. 5x 25

d.

?

Add. Prop.

?

x5

e. Div. Prop.

Lesson 2-7

Addition Property Symmetric Property Transitive Property Substitution Property Reflexive Property Subtraction Property Addition Property Transitive Property Given: AB A F , F A E D , D E C D Prove: A B C D

D E

Lesson 2-5

C F

B A

Proof: Statements

Reasons 1. A B A F , A F E D 1. Given 2. Transitive Property B E D 2. A 3. Given 3. E D C D 4. A B C D


10. Given: AC DF, AB DE A Prove: BC EF

C

B E

D

F

Proof: Statements 1. AC AB BC and DF DE EF 2. AC DF

Reasons 1. Segment Addition Postulate 2. Given

3. AB BC DE EF 3. Substitution 4. Given 4. AB DE 5. Subtraction Property 5. BC EF

Lesson 2-6

1. x 5 ¬6 Add 5 to both sides of the equation. x ¬11 The property that justifies the statement “If x 5 6, then x 11” is the Addition Property. 2. Transitive Property 3. Symmetric Property

Extra Practice

Given

c.

Page 758 1. 2. 3. 4. 5. 6. 7. 8. 9.

?

c. 5x 1 24

e.

1. Sometimes; RS and PS could intersect to form a 45° angle. 2. Sometimes; if the points are collinear, then they lie on one line. 3. Sometimes; the line perpendicular to BC could lie in plane K, but it does not have to. 4. The fact that DF lies in plane R is an instance of Postulate 2.5, which says that if two points lie in a plane, then the entire line containing those points lies in that plane. 5. The fact that E and C are collinear is an instance of Postulate 2.1, which says that through any two points, there is exactly one line. 6. The fact that D, F, and E are coplanar is an instance of Postulate 2.2, which says that through any three points not on the same line, there is exactly one plane. 7. The fact that E and F are collinear is an instance of Postulate 2.1, which says that through any two points, there is exactly one line.

Page 757

Statements

Page 758

Lesson 2-8

1. 9 and 10 form a linear pair, so by the Supplement Theorem, m9 m10 ¬180 141 x 25 x ¬180 166 2x ¬180 2x ¬14 x ¬7

508

2.

3.

4.

5. 6.

7. 8.

9.

m9 141 x 141 7 148 m10 25 x 25 7 32 13 forms a linear pair with the right angle, so by the Supplement Theorem, m13 90 ¬180 m13 ¬90 m13 ¬90 and m13 ¬3x 30, so 3x 30 ¬90 3x ¬60 x ¬20 m11 x 40 20 40 60 m12 x 10 20 10 30 By the Angle Addition Postulate, m14 m15 m16 ¬180 x 25 4x 50 x 45 ¬180 6x 120 ¬180 6x ¬60 x ¬10 m14 x 25 10 25 35 m15 4x 50 4(10) 50 90 m16 x 45 10 45 55 Sometimes; if two complementary angles each measure 45°, they are congruent. Otherwise they are not. Never; the sum of the measures of two angles that form a linear pair is 180, not 90. Sometimes; if two congruent angles each measure 90, then they are supplementary, but otherwise they are not. Always; perpendicular lines are, by definition, lines that intersect at right angles. Always; the measure of one right angle is 90, so the sum of the measures of two right angles is 180. Sometimes; if the intersecting lines are perpendicular they form four right angles. Otherwise they do not.

Page 758 1. 2. 3. 4. 5. 6. 7.

2. By the Corresponding Angles Postulate, 13 5. m13 m5 m13 72 3. By the Vertical Angles Theorem, 4 1. m1 102 (Exercise 1) m4 m1 m4 102 4. 9 and 10 form a linear pair. By the Supplement Theorem, m9 m10 ¬180 102 m10 ¬180 m10 ¬78 5. 5 and 7 form a linear pair. By the Supplement Theorem, m5 m7 ¬180 72 m7 ¬180 m7 ¬108 6. By the Vertical Angles Theorem, 16 13. m13 72 (Exercise 2) m16 m13 m16 72 7. By the Corresponding Angles Postulate, the angles labeled (8x 5)° and 75° are congruent, and so their measures are equal. 8x 5 ¬75 8x ¬80 x ¬10 The angle labeled a° and the angle labeled 75° are corresponding angles, so they are congruent. So a 75.

(8x 5)

75

a

The angle labeled a° and the angle labeled (9y 3)° are consecutive interior angles. By the Consecutive Interior Angles Theorem, the two angles are supplementary. a 9y 3 ¬180 75 9y 3 ¬180 9y 72 ¬180 9y ¬108 y ¬12 8. By the Corresponding Angles Postulate, the angles labeled 55° and (4x 7)° are congruent, and so their measures are equal. 4x 7 ¬55 4x ¬48 x ¬12

Lesson 3-1

LP Planes ABM, OCN, ABC, LMN, and AEP M B , A L , E P , O P , P L , L M , and M N consecutive interior corresponding alternate interior alternate exterior

Page 759

(9y 3)

Lesson 3-2

1. By the Corresponding Angles Postulate, 1 9. m1 m9 m1 102

509

Extra Practice

a (4x 7)

y

9. Find the slopes of RS and TU. 2 1 1 ¬ slope of RS

b

25 ¬ 9 3 or 3 1 0 slope of TU ¬ 2 ( 1) ¬1 3

60 55

By the Angle Addition Postulate, a y b 180. By the Alternate Interior Angles Theorem, a 55 and b 60. By substitution 55 y 60 ¬180 y 115 ¬180 y ¬65

Page 759

The slopes are not the same, so RS and TU are not parallel. The product of the slopes is

(3) 13 or 1. So, AB and CD are neither parallel nor perpendicular. 10. Find the slopes of RS and TU. 7 4 slope of RS ¬ 3 (1) 3 3 ¬ 2 or 2 1) 1 ( slope of TU ¬ 85 ¬2 3

Lesson 3-3

ris e 1. Use the run method. From R(1, 3) to S(4, 1), go down 4 units and right 3 units.

From T(5, 0) to U(1, 1), go up 1 unit and right 6 units.

4 (2)

4 ¬ 2 or 2

ris e 1 run 6

5 3 ¬ slope of TU 13

3. Use the slope formula. Let W(4, 4) be (x1, y1) and V(4, 1) be (x2, y2).

2 ¬ 2 or 1

(y2 y1) m ¬ (x2 x1) 1 4 ¬ 4 (4) 5 or 0, which is undefined

and TU are The slopes are not the same, so RS not parallel. The product of the slopes is 2(1) or 2. So, RS and TU are neither parallel nor perpendicular.

Page 759

4. Use the slope formula. Let W(4, 4) be (x1, y1) and R(1, 3) be (x2, y2).

Lesson 3-4

1. y mx b y 1x (5) yx5 The slope-intercept form of the equation of the line is y x 5. 2. y mx b

(y y ) (x2 x1) 3 4 1 ¬ 1 ( 4) or 5 5. The slope of TU is 1 6 (Exercise 2). A line parallel to TU will also have a slope of 1 6. 1 6. The slope of WR is 5 (Exercise 4). The product 2 1 m ¬

1 y 1 2x 2

The slope-intercept form of the equation of the 1 line is y 1 2x 2. 3. y mx b

of the slopes of two perpendicular lines is 1.

Since 1 5 (5) 1, the slope of a line perpendicular to WR is 5. 7. WV is vertical (with undefined slope). A line perpendicular to WV must be horizontal and thus have a slope of 0. 8. Find the slopes of RS and TU.

y 3x 1 4

y 3x 1 4 The slope-intercept form of the equation of the line is y 3x 1 4. 4. y y1 ¬m(x x1) y 4 ¬3[x (2)] y 4 ¬3(x 2) The point-slope form of the equation of the line is y 4 3(x 2). 5. y y1 ¬m(x x1) y 3 ¬4(x 0) y 3 ¬4x The point-slope form of the equation of the line is y 3 4x.

6 5 RS ¬ slope of 53 ¬1 2

3 0 ¬ slope of TU 4 ( 2) 1 ¬3 6 or 2 are The slopes are the same, so RS and TU parallel.

Extra Practice

2 The product of the slopes is 3 2 3 or 1. So, RS is perpendicular to TU. 11. Find the slopes of RS and TU. 1 5 slope of RS ¬

4 ris e 4 run 3 or 3 ris e 2. Use the run method.

510

6.

slope is 1 3 that contains (2, 2). y y1 ¬m(x x1)

y y1 ¬m(x x1) y (7) ¬2 3 (x 5)

y (2) ¬1 3 [x (2)]

y 7 ¬2 3 (x 5) The point-slope form of the equation of the line is y 7 2 3 (x 5). 7. Find the slope of p by using (0, 1) and (1, 1).

2 y 2 ¬1 3x 3 8 y ¬1 3x 3 The slope-intercept form of the equation of the

1 1 m ¬ 10

8 line is y 1 3x 3. 14. From Exercise 7, the slope of p is 2, so the slope of a line perpendicular to p is 1 2 . Notice that the y-intercept is 0. The slope-intercept form of the equation of the line is y 1 2 x.

2 ¬ 1 or 2

Notice that the y-intercept is 1. The slope-intercept form of the equation of p is y 2x 1. 8. Find the slope of q by using (0, 3) and (3, 0). 3) 0 ( m ¬ 30

Page 760

¬3 3 or 1

Lesson 3-5

1. 9 and 16 are alternate exterior angles for lines c and d cut by transversal n. If alternate exterior angles are congruent, the two lines are parallel. Since 9 16, c d. 2. 10 and 16 are not corresponding, alternate exterior, or alternate interior angles. No lines can be shown to be parallel. 3. 12 and 13 are alternate interior angles for lines c and d cut by transversal n. If alternate interior angles are congruent, the two lines are parallel. Since 12 13, c d. 4. 12 and 14 are consecutive interior angles for lines c and d cut by transversal n. If consecutive interior angles are supplementary, the two lines are parallel. Since m12 m14 180, c d. 5. Explore: From the figure, we know that the angles marked 135° and (2x 15)° are consecutive interior angles for lines r and s. Plan: For line r to be parallel to line s, consecutive interior angles must be supplementary. Solve: 135 2x 15 ¬180 2x 150 ¬180 2x ¬30 x ¬15 Examine: Verify that the two angles are supplementary by substituting the value found for x. 135 2x 15 ¬135 2(15) 15 ¬180 So r s. 6. Explore: From the figure, we know that the angles marked (2x 35)° and (3x 5)° are alternate exterior angles for lines r and s. Plan: For line r to be parallel to line s, alternate exterior angles must be congruent, which means their measures must be equal. Solve: 2x 35 ¬3x 5 2x 40 ¬3x 40 ¬x Examine: Verify that the two angles are congruent by substituting the value found for x. 2x 35 ¬3x 5 2(40) 35 ¬3(40) 5 115 ¬115 So r s.

Notice that the y-intercept is 3. The slope-intercept form of the equation of q is y x 3. 9. Find the slope of r by using (0, 2) and (3, 0). 2) 0 ( m ¬ 30

¬2 3 Notice that the y-intercept is 2. The slope-intercept form of the equation of r is y 2 3 x 2. 10. Find the slope of s by using (0, 0) and (3, 1). 0 1 m ¬ 30

1 1 ¬ 3 or 3

Notice that the y-intercept is 0. The slope-intercept form of the equation of s is y 1 3 x. 11. From Exercise 8, the slope of q is 1, so the slope of a line parallel to q is also 1. Write an equation in point-slope form of the line whose slope is 1 that contains (2, 5). y y1 ¬m(x x1) y (5) ¬1(x 2) y 5 ¬x 2 y ¬x 7 The slope-intercept form of the equation of the line is y x 7. 12. From Exercise 9, the slope of r is 2 3 , so the slope 3 of a line perpendicular to r is 2. Write an equation in point-slope form of the line whose slope is 3 2 that contains (0, 1). y y1 ¬m(x x1) y 1 ¬3 2 (x 0) y 1 ¬3 2x y ¬3 2x 1

The slope-intercept form of the equation of the line is y 3 2 x 1. 13. From Exercise 10, the slope of s is 1 3 , so the

slope of a line parallel to s is also 1 3 . Write an equation in point-slope form of the line whose

511

Extra Practice

7. Explore: From the figure, we know that the angles marked (2x 92)° and (66 11x)° are corresponding angles for lines r and s. Plan: For line r to be parallel to line s, corresponding angles must be congruent, which means their measures must be equal. Solve: 2x 92 ¬66 11x 13x 92 ¬66 13x ¬26 x ¬2 Examine: Verify that the two angles are congruent by substituting the value found for x. 2x 92 ¬66 11x 2(2) 92 ¬66 11(2) 88 ¬88 So r s.

Page 760

y

p

x (0, 2)

y y1 ¬m(x x1) y (2) ¬3 2 (x 0) y 2 ¬3 2x y ¬3 2x 2 Next, use a system of equations to determine the point of intersection of lines m and p.

Lesson 3-6

1 m: y ¬2 3x 2

1. Since the distance from a line to a point not on the line is the length of the segment perpendicular to the line from the point, draw T P so that P T RS. Q P

R

T

m

p: y ¬3 2x 2 1 Substitute 2 3 x 2 for y in the second equation. 2x 1 ¬3x 2 3 2 2 2 3 x x ¬1 2 3 2 2 1 3 5 x ¬ 6 2 15 x ¬ 13 15 for x in the first equation. Substitute 13 15 1 y ¬2 3 13 2 7 y ¬ 2 6 15 7 The point of intersection is 13 , 26 .

S

2. Since the distance from a line to a point not on the line is the length of the segment perpendicular to the line from the point, extend . L K and draw J M so that J M KL

J

Then, use the Distance Formula to determine the


K

L

15 7 0 2) 13 6 (

2

3. In octagon ABCDEFGH, A B F E . Therefore E B F E . So B E represents the distance from B . to FE A B H

C

G

D

2

¬

M

15 52 22 5 15 ¬ 52 or 52 5 2

52 15 or about The distance between the lines is 52 2.08 units. 5. Solve a system of equations to find the endpoints of a segment that is perpendicular to : y 2x 4 and m: y 2x 5 which is the same as y 2x 5. The slope of lines and m is 2. First, write an equation of a line p perpendicular to and m. The slope of p is the opposite reciprocal of 2, or 1 2 . Use the y-intercept of line , (0, 4), as one of the endpoints of the perpendicular segment.

E F 4. Solve a system of equations to find the endpoints of a segment that is perpendicular to 2 1 : y 2 3 x 2 and m: y 3 x 2 . The slope of lines 2 and m is 3. First, write an equation of a line p perpendicular to and m. The slope of p is the opposite reciprocal of 32, or 23. Use the y-intercept of line , (0, 2), as one of the endpoints of the perpendicular segment.

y (0, 4)

p

x

m

Extra Practice

2

512

3 Substitute 1 4 x 2 for y in the second equation.

y y1 ¬m(x x1)

3 1 4 x 2 ¬4x 1

y 4 ¬1 2 (x 0)

3 1 4 x 4x ¬ 2 1

y 4 ¬1 2x

1 7 5 4 x ¬ 2

y ¬1 2x 4

10 x ¬ 17

Next, use a system of equations to determine the point of intersection of lines m and p. m: y ¬2x 5 p: y ¬1 2x 4 Substitute 2x 5 for y in the second equation.

10 Substitute 17 for x in the second equation.

23 y 17

2x 5 ¬1 2x 4

2

2

9 5 81 9 ¬ 5 or 5 5

5 9 The distance between the lines is 5 or about 4.02 units. 6. Solve a system of equations to find the endpoints of a segment that is perpendicular to and m, 3 where : x 4y 6 is the same as y 1 4x 2 and m: x 4y 4 is the same as y 1 4 x 1. . The slope of lines and m is 1 4 First, write an equation of a line p perpendicular to and m. The slope of p is the opposite reciprocal of 1 4 , or 4. Use the y-intercept of line m, (0, 1), as one of the endpoints of the perpendicular segment.

1 7

5 appears to intersect line at R 3 2 , 2 . Use the Distance Formula to find the distance between point P and line . y

Q

B R

y

m

2

17 10 or about The distance between the lines is 17 2.43 units. 7. 1. Graph line and point P. Place the compass point at point P. Make the setting wide enough so that when an arc is drawn, it intersects in two places. Label these points of intersection A and B. 2. Put the compass at point A and draw an arc above line . 3. Using the same compass setting, put the compass at point B and draw an arc to intersect the one drawn in step 2. Label the point of intersection Q. PQ. PQ . Label point R at the 4. Draw intersection of PQ and . The segment constructed from point P(2, 1) perpendicular to the line ,

1 8 0 4 151 5

10 17 10 0 10 ¬ 17 or 17

1 8 1 1 distance between (0, 4) and 5 , 5 . d ¬ (x2 x1)2 (y2 y1)2 2

10 0 17 7 1

213

¬

Then, use the Distance Formula to determine the

¬


10 23 The point of intersection is 17 , 17 . Then, use the Distance Formula to determine the

2x 1 2 x ¬5 4 5 x ¬9 2 1 8 x ¬ 5 18 Substitute 5 for x in the first equation. 1 8 y 2 5 5 11 y 5 18 11 The point of intersection is 5 , 5 .

10 y 4 17 1

p

A

x

O

P x

d ¬ (x2 x1)2 (y2 y1)2 2 5 (1) 3 2 2

2

¬

2

7 2 4 9 7 ¬ 2 or 2

y y1 m(x x1) y 1 ¬4(x 0) y 1 ¬4x y ¬4x 1 Next, use a system of equations to determine the point of intersection of lines and p. 3 : y 1 4 x 2 p: y 4x 1

2

2 7 The distance between P and is 2 units. 8. 1. Graph line and point P. Place the compass point at point P. Make the setting wide enough so that when an arc is drawn, it intersects in two places. Label these points of intersection A and B.

513

Extra Practice

9. TAC is isosceles with T A A C , so TA AC. Therefore, 3b 1 ¬4b 11 1 11 ¬3b 4b 12 ¬b Next, substitute to find the length of each side. TA 3b 1 AC 4b 11 3(12) 1 4(12) 11 37 37 TC 6b 2 6(12) 2 70 For TAC, b 12, TA AC 37, and TC 70.

2. Put the compass at point A and draw an arc above line . 3. Using the same compass setting, put the compass at point B and draw an arc to intersect the one drawn in step 2. Label the point of intersection Q. 4. Draw PQ. PQ . Label point R at the and . The segment constructed intersection of PQ from point P(2.5, 3) perpendicular to the line , appears to intersect line at R(1.4, 3.8). Use the Distance Formula to find the distance between point P and line . y

A

Q

Page 761

R

P

B x

O

d ¬ (x2 x1)2 (y2 y1)2 ¬[1.4 (2 .5)]2 [3.8 3]2 ¬1.85 or about 1.4 The distance between P and is approximately 1.4 units.

Page 760

Lesson 4-1

1. All three angles are congruent, so the triangle is equiangular. 2. The triangle has one right angle. So the triangle is a right triangle. 3. The triangle has one obtuse angle ( 90°). So the triangle is obtuse. 4. Right triangles have one right angle. So, DAB, ABC, BCD, and ADC are right triangles. 5. Obtuse triangles have one obtuse angle. ABE and CDE are obtuse. 6. Acute triangles have all acute angles. BEC and AED are acute. 7. Isosceles triangles have at least two sides congruent. So, ABE, CDE, BEC, and AED are isosceles. 8. Since MNO is equilateral, each side has the same length. So MN NO. Therefore, 5a ¬4a 6 a ¬6 Next, substitute to find the length of each side. MN 5a NO 4a 6 5(6) 4(6) 6 30 30 MO 7a 12 7(6) 12 30 For MNO, a 6 and the measure of each side is 30.

Extra Practice

Lesson 4-2

1–4. Find m2 first because the measures of two angles of the triangle are known. m2 50 70 180 m2 120 ¬180 m2 ¬60 1 and 2 are congruent vertical angles. So m1 60. 1 and 4 form a linear pair. m1 m4 ¬180 60 m4 ¬180 m4 ¬120 Use the Angle Sum Theorem to find m3. m3 65 m1 ¬180 m3 65 60 ¬180 m3 125 ¬180 m3 ¬55 Therefore, m1 60, m2 60, m3 55, and m4 120. 5. Use the Angle Sum Theorem. m5 32 54 ¬180 m5 86 ¬180 m5 ¬94 6. 5 and 6 form a linear pair. From Exercise 5, m5 94. m5 m6 ¬180 94 m6 ¬180 m6 ¬86 7. 5 and 7 are vertical angles. So 5 7. m7 94 8. 6 and 8 are vertical angles. So 6 8. m8 86 9. Use the Angle Sum Theorem. m9 m8 42 ¬180 m9 86 42 ¬180 m9 128 ¬180 m9 ¬52 10. Use the Angle Sum Theorem. m10 m7 62 ¬180 m10 94 62 ¬180 m10 156 ¬180 m10 ¬24

Page 761 1. 2. 3. 4.

514

Lesson 4-3

ABC FDE JKH JIH RTS UVW LMN NOP

5. Given: ANG NGA NGA GAN Prove: AGN is equilateral and equiangular.

G

A

Proof: Statements 1. ANG NGA

Reasons 1. Given

2. A N N G , A N

2. CPCTC

3. NGA GAN

3. Given

Page 761

2. Definition of equilateral triangle 3. Given

3. W S W I

O N

1. Use the Distance Formula to show that the corresponding sides are congruent. RS ¬ [6 (4)]2 [2 4]2 ¬ 4 4 or 8 JK ¬ [6 4 ]2 [ 2 ( 4)]2 ¬ 4 4 or 8 ST ¬ [4 (2)]2 [4 2]2 ¬ 4 4 or 8 KL ¬ [4 2 ]2 [ 4 ( 2)]2 ¬ 4 4 or 8 RT ¬ [6 (2)]2 [2 2]2 ¬ 16 or 4 JL ¬ [6 2 ]2 [ 2 ( 2)]2 ¬ 16 or 4 RS JK, ST KL, and RT JL. By definition of congruent segments, all corresponding segments are congruent. Therefore, RST JKL by SSS. 2. Use the Distance Formula to show that corresponding sides are not congruent. RS ¬ [6 (4)]2 [3 7]2 ¬ 4 1 6 or 20 2 (3 JK ¬ (2 5) 7)2 ¬ 9 1 6 or 5 Since RS JK, RST JKL. 3. Given: GWN is W equilateral. W WS I S I SWG IWN Prove: SWG IWN Proof: G N

2. W G W N

5. SAS

Proof:

Lesson 4-4

Reasons 1. Given

5. SWG IWN

D

8. Definition of equiangular triangle

Statements 1. GWN is equilateral.

4. Given

4. Given: ANM ¬ANI DI ¬O M D N ¬N O Prove: DIN OMN I M A

N

4. N G G A , N G 4. CPCTC 5. Transitive Property 5. A N N G G A 6. AGN is equilateral. 6. Definition of equilateral triangle 7. Transitive Property 7. A N G 8. AGN is equiangular.

4. SWG IWN

Statements 1. ANM ANI

Reasons 1. Given

2. IN M N

2. CPCTC

3. D I O M

3. Given

4. N D N O

4. Given

5. DIN OMN

5. SSS

Page 762

Lesson 4-5

1. Given: TEN is isosceles with base T N . 1 4, T N Prove: TEC NEA

E

1 2

T

C

3 4

A

N

Proof: If TEN is isosceles with base T N , then E T N E . Since 1 4 and T N are given, then TEC NEA by AAS. 2. Given: S W, S V Y S Y W Prove: S T W V Y T W Proof: S W and S Y Y W are given, and SYT WYV since vertical angles are congruent. Then SYT WYV by ASA and T S W V by CPCTC. 3. Given: 1 2, P L 3 4 1 2 Prove: PT LX R 4

T

3

X

Proof: 1

2

3

Given

4 Given

PXT

TX

TX

Reflexive Prop.

LTX

AAS

PT

LX

CPCTC

515

Extra Practice

4. Given: FP ML, MP FL

F 1

Prove: MP FL

4

FL || MP

Given

Given

3

4

1

Alt. Int. Th.

2 Alt. Int. Th.

FLP

3

2

P Proof: FP || ML

• Since Z is on the x-axis, its y-coordinate is 0. Its x-coordinate is 4b because the base of the triangle is 4b units long. • Because XYZ is equilateral and thus Y X Z Y , the x-coordinate of Y is halfway between X and Z at 2b. We cannot determine the y-coordinate in terms of b, so call it c.

L

M

y

Y(2b, c) PL

Z(4b, 0)

PL

Reflex. Prop.

3. • Use the origin as vertex S of the triangle. • Place the base of the triangle, S R , along the positive x-axis. • Position the triangle in the first quadrant. • Since R is on the x-axis, its y-coordinate is 0. Its x-coordinate is (3 a) because the base of the triangle is (3 a) units long. • Because R T is vertical, the x-coordinate of T is (3 a). And because RT 3 a, the y-coordinate of T is (3 a).

MPL

ASA

MP

FL

CPCTC

Page 762

Lesson 4-6

1. DAB is opposite B D and DBA is opposite A D , so DAB DBA. 2. FBG is opposite F G and FGB is opposite B F , so FBG FGB. 3. BEF is opposite B G and BGF is opposite B E , so BEF BGF. 4. By the converse of the Isosceles Triangle Theorem, the sides opposite congruent angles are congruent. So, F B F E . 5. By the converse of the Isosceles Triangle Theorem, the sides opposite congruent angles are congruent. So, B A B C . 6. By the converse of the Isosceles Triangle Theorem, the sides opposite congruent angles are congruent. So, B D C D .

Page 762

y

R(3 a, 0)

y

C(1–8b, c) E(1–4b, 0)

D(0, 0)

x

5. Vertex A is on the y-axis, at an unspecified distance from the origin. Its coordinates are (0, b). Since B is on the x-axis, the y-coordinate of B is 0. Because ABC is isosceles, the x-coordinate of A is halfway between the x-coordinate of B and C. So the x-coordinate of B is a. The coordinates of B are (0, a). 6. Side F E can be seen to be vertical, so the x-coordinate of F is the same as the x-coordinate of E, namely b. F is the same distance from E as E is from the origin, namely b units. So the y-coordinate of F is b. The coordinates of F are (b, b).

A(r–2, b) C(r, 0) x

2. • Use the origin as vertex X of the triangle. • Place the base of the triangle, X Z , along the positive x-axis. • Position the triangle in the first quadrant.

Extra Practice

x

4. • Use the origin as vertex D of the triangle. • Place the base of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since E is on the x-axis, its y-coordinate is 0. Its x-coordinate is 1 4 b because the base of the b units long. triangle is 1 4 • Because CDE is equilateral and thus C D C E, the x-coordinate of C is halfway between D and E at 1 8 b. We cannot determine the y-coordinate in terms of b, so call it c.

Lesson 4-7

B(0, 0)

T(3 a, 3 a)

S(0, 0)

1. • Use the origin as vertex B of the triangle. • Place the base of the triangle along the positive x-axis. • Position the triangle in the first quadrant. • Since C is on the x-axis, its y-coordinate is 0. Its x-coordinate is r because the base of the triangle is r units long. • Since ABC is isosceles, the x-coordinate of A is halfway between 0 and r or 2r. We cannot determine the y-coordinate in terms of r, so call it b. y

x

X(0, 0)

516

7. Vertex I is on the y-axis, at an unspecified distance from the origin; its coordinates are (0, b). Since G is on the x-axis, the y-coordinate of G is 0. Because GHI is isosceles, the x-coordinate of I is halfway between the x-coordinates of G and H. So, the x-coordinate of G is a 2. The coordinates of G are (a 2, 0).

Page 763

8. Always; unlike altitudes, the angle bisectors of a triangle always run through the interior of the triangle and intersect inside the triangle.

Page 763

Lesson 5-2

1. The side opposite TPS is longer than the side opposite TSP, so mTPS mTSP. 2. The side opposite PRZ is longer than the side opposite ZPR (27.5 12 24.5), so mPRZ mZPR. 3. The side opposite SPZ is shorter than the side opposite SZP (17.2 34), so mSPZ mSZP. 4. The side opposite SPR is the same length as the side opposite SRP (15 19 34), so mSPR mSRP. 5. Given: FH FG Prove: m1 m2 E H

Lesson 5-1

1. Assume that S is the circumcenter. Then AP is the perpendicular bisector of CB. So CP PB. 7x 1 ¬6x 3 x ¬4 CP ¬7x 1 CP ¬7 4 1 27 2. Find a. Because S is the incenter, CT bisects ACB. mACT ¬1 2 (mACB) 15a 8 ¬1 2 (74) 15a 8 ¬37 15a ¬45 a ¬3 Find mACT. mACT 15a 8 mACT 15(3) 8 mACT 37 3. Find b. Because Z is the centroid, O is the midpoint of T R . TO ¬OR 7b 5 ¬13b 10 5 10 ¬7b 13b 15 ¬6b 2.5 ¬b Find TR. TR TO OR TR 7b 5 13b 10 TR 20b 5 TR 20(2.5) 5 TR 45 4. Find n. Because Z is the centroid,

1 2

G F

Proof: Statements 1. FH FG

Reasons 1. Given

2. mFGH m2

2. If one side of a triangle is longer than another, the angle opposite the longer side is greater than the angle opposite the shorter side. 3. Exterior Angle Inequality Theorem 4. Transitive Property of Inequality

3. m1 mFGH 4. m1 m2

bisects SRT. 6. Given: RQ Prove: mSQR mSRQ

ZR ¬2 3 XR

R

S

10n 4 ¬2 3 (19n 14) 3 28 n 10n 4 ¬38 3 3 8 2 8 0n 3n ¬4 3 4 0 8 3 n ¬ 3

Q

T

Proof: Statements bisects SRT. 1. RQ 2. SRQ QRT

Reasons 1. Given

2. Definition of angle bisector 3. mSRQ mQRT 3. Definition of congruent angles 4. mSQR mQRT 4. Exterior Angle Inequality Thorem 5. mSQR mSRQ 5. Substitution

n ¬5 Find ZR. ZR 10n 4 ZR 10(5) 4 ZR 54 5. Sometimes; they are the same for an equilateral triangle but not for all triangles. 6. Sometimes; the three altitudes intersect inside the triangle when the triangle is acute, but not when it is obtuse. 7. Always; the symmetry of an equilateral triangle guarantees this.

Page 763

Lesson 5-3

1. ABC XYZ 2. An angle bisector of an equilateral triangle is not a median. does not bisect ARC. 3. RS

517

Extra Practice

4. Given: AOY AOX XO Y O is not the angle bisector of XAY. Prove: AO X

5. Check each inequality. ? ? ? 15 20¬ 30 15 30¬ 20 20 30¬ 15 35¬ 30 ✓ 45¬ 20 ✓ 50¬ 15 ✓ All of the inequalities are true, so 15, 20, and 30 can be the lengths of the sides of a triangle. ?

6. 1 3 5 4

¬5 Because the sum of the two smaller measures is not greater than the largest measure, the measures cannot be the lengths of the sides of a triangle.

O

A

Y Indirect Proof: Step 1: Assume AO is the angle bisector of XAY. is the angle bisector of XAY, then Step 2: If AO XAO YAO. AOY AOX is given as true, and A O A O by the Reflexive Property of Congruence. Then XAO YAO by ASA, and O X Y O by CPCTC. Step 3: This conclusion contradicts the given fact O X Y O . Thus, AO is not the angle bisector of XAY. 5. Given: RUN Prove: There can be no more than one right angle in RUN. Indirect Proof: Step 1: Assume RUN has two right angles. Step 2: By the Angle Sum Theorem, mR mU mN 180. If you substitute 90 for two of the angle measures, since the triangle has two right angles, then 90 90 mN 180 or 180 mN 180. Step 3: This conclusion means that mN 0. This is not possible if RUN is a triangle. Thus, there can be no more than one right angle in RUN.

Page 764

?

7. 2.5 3.5 6.5 6

¬6.5 Because the sum of the two smaller measures is not greater than the largest measure, the measures cannot be the lengths of the sides of a triangle. 8. Check each inequality. ? ? ? 0.3 0.4¬ 0.5 0.3 0.5¬ 0.4 0.4 0.5¬ 0.3 0.7¬ 0.5 ✓ 0.8¬ 0.4 ✓ 0.9¬ 0.3 ✓ All of the inequalities are true, so 0.3, 0.4, and 0.5 can be the lengths of the sides of a triangle. 9. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 6 10 n 6 n 10 n 10 6 16 n or n 16 n4 n 4 Graph the inequalities on the same number line. n 16 16

n4 4

n 4 4

Lesson 5-4

intersection

?

1. 2 2 ¬6 4 ¬6 Because the sum of the two smaller measures is not greater than the largest measure, the measures cannot be the lengths of the sides of a triangle. 2. Check each inequality. ?

?

4

16

The range of values that fits all three is 4 n 16. 10. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 25n 2n5 n52 7 n or n 7 n3 n 3 Graph the inequalities on the same number line.

?

2 4¬¬3 3 4¬¬2 2 3 ¬4 5 ¬4 ✓ 6¬¬3 ✓ 7¬¬2 ✓ All of the inequalities are true, so 2, 3, and 4 can be the lengths of the sides of a triangle. 3. Check each inequality. ? ? ? 6 8¬ 10 6 10¬ 8 8 10¬ 6 14¬ 10 ✓ 16¬ 8 ✓ 18¬ 6 ✓ All of the inequalities are true, so 6, 8, and 10 can be the lengths of the sides of a triangle.

7

n3 3

n 3

?

4. 1 1 2 2 ¬2 Because the sum of the two smaller measures is not greater than the largest measure, the measures cannot be the lengths of the sides of a triangle.

3 intersection 3

7

The range of values that fits all three is 3 n 7.

Extra Practice

n7

518

11. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 12 20 n 12 n 20 n 20 12 32 n or n 32 n8 n 8 Graph the inequalities on the same number line.

14. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 32 34 n 32 n 34 n 34 32 66 n or n 66 n2 n 2 Graph the inequalities on the same number line.

n 32

n 66

32

66

n2

n8

2

8

n 8

8

n 2

2

intersection

intersection 8

2

32

66

The range of values that fits all three is 2 n 66. 15. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 2 29 n 2 n 29 n 29 2 31 n or n 31 n 27 n 27 Graph the inequalities on the same number line.

The range of values that fits all three is 8 n 32. 12. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 88n 8n8 n88 16 n or n 16 n0 n0 Graph the inequalities on the same number line. 16

n 31

31

n 16

n 27 27

n0

n 27

0 27

intersection 0

intersection

16

27

The range of values that fits all three is 27 n 31. 16. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 25 80 n 25 n 80 n 80 25 105 n or n 105 n 55 n 55 Graph the inequalities on the same number line.

The range of values that fits all the inequalities is 0 n 16. 13. Let the measure of the third side be n, and solve each inequality to determine the range of values for n. 18 36 n 18 n 36 n 36 18 54 n or n 54 n 18 n 18 Graph the inequalities on the same number line. 54

31

n 105

n 54

105

n 18

n 55

18

55

n 18

18

n 55 55

intersection 18

intersection

54

55


105


519

Extra Practice

17. Given: RS RT Prove: UV VS UT

U

6.

V

B 6.56 15

R T

25

S

A 55

Proof:

15

Statements 1. RS RT 2. UV VS US 3. US UR RS

Reasons

4. UV VS UR RS

4. Substitution

5. UV VS UR RT 6. UR RT UT

5. Substitution

7. UV VS UT

7. Transitive Property of Inequality

6. Triangle Inequality Theorem

7.

B

A

2x 7

D

B A A D , A C A C , and mCAD mCAB. By the SAS Inequality, CD CB. CD CB 2x 7 6.56 2x 13.56 x 6.78 Also, by the Triangle Inequality Theorem, AB AD BD. AB AD BD 15 15 6.56 2x 7 30 2x 0.44 30.44 2x 15.22 x The two inequalities can be written as the compound inequality 6.78 x 15.22.

1. Given 2. Triangle Inequality Theorem 3. Segment Addition Postulate

18. Given: quadrilateral ABCD Prove: AD CD AB BC

C

3x 1

A

3x 1

D

1. quadrilateral ABCD

6. AD CD AB BC

6. Addition Property of Inequality

4. AC BC AB

Page 764

D

Reasons

5. AD CD BC AB

3. AD CD AC AB AC BC

5x 21

C

Because ABD is equilateral, mABD 60 and so mABD mDBC. Since A B C B and D B B D , the SAS inequality allows us to conclude that AD DC. AD DC 3x 1 5x 21 1 21 3x 5x 20 2x 10 x Also, the measure of any side is always greater than 0. 5x 21 0 5x 21 x 4.2 The two inequalities can be written as the compound inequality 4.2 x 10.

Page 764

Lesson 5-5

1. XZ 32 and OZ 30, so XZ OZ. 2. In ZIO and ZUX, Z I U X , IO U Z , and XZ OZ. The SSS inequality allows us to conclude that mZIO mZUX. 3. AEZ is an isosceles triangle with A E A Z . By the Isosceles Triangle Theorem, the angles opposite congruent sides are congruent. So mAEZ mAZE. 4. IO 18 and AE 30, so IO AE. 5. In AZE and IZO, A Z Z O , Z E Z I, and AE IO. The SSS inequality allows us to conclude that mAZE mIZO. Extra Practice

3x 1

C

1. Given 2. Through any two points there is exactly one line. 3. Triangle Inequality Theorem 4. Subtraction Property of Inequality 5. Transitive Property of Inequality

C . 2. Draw A

45

3x 1

Proof: Statements

B

Lesson 6-1

1. Write the given information, using x for the actual house width in the substitution. model height model width actual width actual height 1 1 6 6 3 x

1 x (63)(16) x 1008 The actual width of the house is 1008 in., which equals 1008 12 or 84 ft.

520

2. Write the given information, using x for the smaller length. x¬ 2 64 x 3 x 3¬ (64 x)(2) 3x¬ 128 2x 5x¬ 128 x¬ 25.6 The two lengths are 25.6 in. and 64 25.6 or 38.4 in. 3.

Page 765

4 x 1 26 3

(x 4)(3) 26(1) 3x 12 26 3x 38 3 8 x 3 4.

AC 7.5 XZ 3 or 2.5

The ratios of the measures of the corresponding sides are equal, and the corresponding angles are congruent, so ABC XYZ. 2. S W. T X. U Y. R V. Thus, all of the corresponding angles are congruent. Now determine whether corresponding sides are proportional.

1 3x 5 14 7

(3x 1)(7) 14(5) 21x 7 70 21x 63 x3 5.

3 x x1 4 ¬ 5

(x 3)(5)¬ 4(x 1) 5x 15¬ 4x 4 5x 4x¬ 15 4 x¬ 19 6.

Lesson 6-2

1. By the Angle Sum Theorem, mA 21.8 38.2 180, which means that mA 180 21.8 38.2 or 120. So mA mX, and therefore A X. Similarly, mY 120 38.2 180 and mY 180 120 38.2 or 21.8. So mB mY, and therefore B Y. Since mC mZ, C Z. Thus, all corresponding angles are congruent. Now determine whether corresponding sides are proportional. AB 12 .5 BC 17 .5 XY 5 or 2.5 YZ 7 or 2.5

R S 4 or 1.5 VW 8

ST 6 W X 4 or 1.5

TU 4 or 1.5 XY 8

RU 10 or 1.5 2 0 VY

3

3

3

The ratios of the measures of the corresponding sides are equal, and the corresponding angles are congruent, so polygon RSTU polygon VWXY. 3. The triangle remains the same shape and size, but each vertex is shifted to the left 3 units and down 3 units. R(3, 6) becomes R (0, 3), S(1, 2) becomes S (2, 1), and T(3, 1) becomes T (0, 4). The new triangle is both congruent and similar to the original. 4. The triangle remains the same shape, but the length of each side is one half the length of the corresponding sides of the original triangle. The new triangle is similar to the original.

2x 2 1 2x 1 3

(2x 2)(3) (2x 1)(1) 6x 6 2x 1 6x 2x 6 1 4x 7 x 7 4 7. Rewrite 9 : 6 : 5 as 9x : 6x : 5x and use those measures for the sides of the triangle. Write an equation to represent the perimeter of the triangle as the sum of the measures of its sides. 9x 6x 5x¬ 100 20x¬ 100 x¬ 5 Use this value of x to find the measures of the sides of the triangle. 9x 9(5) 45 6x 6(5) 30 5x 5(5) 25 The side lengths are 45 inches, 30 inches, and 25 inches. 8. Rewrite 13 : 16 : 21 as 13x : 16x : 21x and use those measures for the angles of the triangle. Write an equation for the sum of the angles, using the Angle Sum Theorem. 13x 16x 21x¬ 180 50x¬ 180 x¬ 3.6 Use this value of x to find the measures of the angles of the triangle. 13x 13(3.6) 46.8 16x 16(3.6) 57.6 21x 21(3.6) 75.6 The angle measures are 46.8, 57.6, and 75.6.

Page 765

Lesson 6-3

1. mN mX, so N X. If the measures of the corresponding sides that include the angles are proportional, then the triangles are similar. XZ YX 12 .5 1 5 LN 5 or 2.5 and NM 6 or 2.5 YX X Z By substitution, LN NM . So, by SAS Similarity,

LNM YXZ. 2. mC mR so C R. By the Angle Sum Theorem, mB 70 22 180, which means that mB 180 70 22 or 88. Therefore mB mS, and so B S. By AA Similarity, ABC TSR.

521

Extra Practice

25 8x 2 15 ¬ 3x 6 8x 2 5¬ 3 3x 6

3. Since RT SQ, TRV QSV and RTV SQV. By AA Similarity, RTV SQV. By the definition of similar polygons,

5(3x 6)¬ 3(8x 2) 15x 30¬ 24x 6 15x 24x¬ 30 6 9x¬ 36 x¬ 4 Find AD and DR by substitution. AD 3x 6 AD 3(4) 6 AD 18 DR 8x 2 DR 8(4) 2 DR 30 QR UD, so U Q and D R since they are pairs of corresponding angles. AQR AUD by AA similarity. QR AR , By the definition of similar polygons, U D AD and by the Segment Addition Postulate, AR AD DR. Use substitution.

TV R V SV QV .

By the Segment Addition Postulate, RV RS SV and TV TQ QV. SV QV RS TQ SV QV 24 15 7 x9 12 7x 9 ¬ 24 7x 24 3 7x 9 ¬ 2

(7x 24)(2)¬ (7x 9)(3) 14x 48¬ 21x 27 14x 21x¬ 48 27 7x¬ 21 x¬ 3 Use the definition of similar polygons and substitution again. R T TV SQ Q V QV R T TQ SV QV 24 R T 12 18 24 R T 3 18 2

QR DR AD AD U D QR 30 18 18 15 QR 48 18 15 QR 8 3 15 QR 158 3

2(RT) (18)(3) 2(RT) 54 RT 27 Finally, find SV by substitution. SV 7x 9 SV 7(3) 9 SV 30 So RTV SQV, x 3, RT 27, and SV 30. OP , LMN OPN and MLN 4. Since LM PON. By AA Similarity, MNL PNO. Use the definition of similar polygons.

QR 40 So x 4, AD 18, DR 30, and QR 40. 3. By the Converse of the Triangle Proportionality Theorem, x should be chosen so that X L YM LD M D.

Substitute known values and solve for x.

LN M N PN ¬ ON 2 5x 7 x 5 ¬ 5

5 3 x 9 3

3(x 3) 9(5) 3x 9 45 3x 36 x 12 4. By the Converse of the Triangle Proportionality Theorem, x should be chosen to that X L YM LD M D. Substitute known values and solve for x.

(5x 2)(5)¬ (x 5)(7) 25x 10¬ 7x 35 25x 7x¬ 10 35 18x¬ 45 x¬ 2.5 Find PN and MN by substitution. PN x 5 MN 5x 2 PN 2.5 5 MN 5(2.5) 2 PN 7.5 MN 10.5 So MNL PNO, x 2.5, PN 7.5, and MN 10.5.

Page 765

4 3 3x 1 ¬ x 7

4(x 7)¬ (3x 1)(3) 4x 28¬ 9x 3 4x 9x¬ 28 3 5x¬ 25 x¬ 5 5. By the Converse of the Triangle Proportionality Theorem, x should be chosen to that

Lesson 6-4

1. From the Triangle Proportionality Theorem, IJ LK . Substitute the known measures. H I LH 8 IJ 2 8 2 1 8 IJ 28 2 1 3 2 IJ 3 or 10 2 3

X L YM LD M D.

Substitute known values and solve for x.

2. From the Triangle Proportionality Theorem, QU D R AU AD . Substitute the known measures. Extra Practice

522

5 3 5x 1 ¬ 5x 6

2.

5(5x 6)¬ (5x 1)(3) 25x 30¬ 15x 3 25x 15x¬ 30 3 10x¬ 33 x¬ 3.3

Page 766

Lesson 6-5

AC BC 1. By the definition of similar polygons, D E BE . Substitute known values.

3.

AC 15 5 6 15 AC 5 6

4.

AC 12.5 The perimeter of ABC is 15 17.5 12.5 or 45 units. 2. Let x represent the perimeter of RST. Use the Proportional Perimeter Theorem.

5.

perimeter of XYZ XZ R T perimeter of RST

6.

8 2x2 12 2 2 x2 3

Page 766

2x 3(22) 2x 66 x 33 The perimeter of RST is 33 units. 3. Let x represent the perimeter of LMN. The perimeter of NXY is 14 11 9 or 34. Use the Proportional Perimeter Theorem.

Lesson 7-1

1. Let x represent the geometric mean. x 8 x 1 2

x2 96 x 96 x 46 The geometric mean is 46 or approximately 9.8. 2. Let x represent the geometric mean.

perimeter of NXY YN LN perimeter of LMN

15 x x ¬ 20

9 3x4 27 3 4 1 x 3

x2¬ 300 x¬ 300 x¬ 103 The geometric mean is 103 or approximately 17.3. 3. Let x represent the geometric mean. x 1 x 2 x2 2 x 2 The geometric mean is 2 or approximately 1.4. 4. Let x represent the geometric mean. x 4 x 1 6 2 x 64 x 64 x8 The geometric mean is 8. 5. Let x represent the geometric mean.

1x 3(34) x 102 The perimeter of LMN is 102 units. 4. Let x represent the perimeter of GHI. Use the Proportional Perimeter Theorem. perimeter of ABC AB ¬ GH perimeter of GHI 6 ¬ 2x5 10 3 2 ¬ x5 5

3x¬ 5(25) 3x¬ 125 12 5 x¬ 3

12 5 2 The perimeter of GHI is 3 or 41 3 units.

Page 766

There are 1 large shaded square, 3 small shaded squares, and 9 very small shaded squares, or 13 shaded squares in all. Use a calculator. The sequence of values is approximately 6, 1.565, 1.118, 1.028, 1.007, 1.002, .... The values converge to 1. Use a calculator. The sequence of values is approximately 0.4, 1.741, 11.175, 5345856.098, and then comes an overflow error. The values approach positive infinity. Use a calculator. The sequence of values is approximately 0.5, 0.125, 0.002, .... The values converge to 0. Use a calculator. The sequence of values is 10, 59049, and then comes an overflow error. The values approach positive infinity.

3 2 x x 62

Lesson 6-6

1.

x2 36 x 36 x6 The geometric mean is 6.

There are 1 large shaded square and 3 small shaded squares, or 4 shaded squares in all.

523

Extra Practice

EF (2 3 )2 (3 2)2 2 2 (1) 1 2 2 (3 DF (2 0) 1)2 22 22 8 By the converse of the Pythagorean Theorem, if the sum of the squares of the measures of two sides of a triangle equals the square of the measure of the longest side then the triangle is a right triangle. DE 2¬ DF 2 EF 2 (10 )2¬ (8 )2 (2 )2 10¬ 8 2 10¬ 10 Since the sum of the squares of two sides equals the square of the longest side, DEF is a right triangle. 2. Use the Distance Formula to determine the lengths of the sides. d (x2 x1)2 (y2 y1)2

6. Let x represent the geometric mean. 1 2

x x 10

x2 5 x 5 The geometric mean is 5 or approximately 2.2. 7. Let x represent the geometric mean. 3 x 8 x 1 2

3 x2 16 3 x

16 3 x 4

3 The geometric mean is 4 or approximately 0.4. 8. Let x represent the geometric mean. 2

2 x 2 3 x 2 3 2 x 2 x 3 2 6 x 2

2 DE [3 (2)] (1 2)2 2 2 5 ( 3) 34 EF (4 3)2 (3 (1)]2 2 2 (7) (2 ) 53 DF [4 (2)]2 ( 3 2)2 2 2 (2) (5 ) 29 By the converse of the Pythagorean Theorem, if the sum of the squares of the measures of two sides of a triangle equals the square of the measure of the longest side then the triangle is a right triangle. EF 2¬ DE2 DF 2 (53 )2¬ (34 )2 (29 )2 53¬ 34 29 53¬ 63 Since the sum of the squares of two sides does not equal the square of the longest side, DEF is not a right triangle. 3. Use the Distance Formula to determine the lengths of the sides. d (x2 x1)2 (y2 y1)2

6 The geometric mean is 2 or approximately 1.2. 9. Let x represent the geometric mean. 1

10 x x 7 10

7 x2 100 7 x 100 7 x 10

7 The altitude is 10 or approximately 0.3. 10. Let x represent the altitude. 12 x x 3 2 x2 384 x 384 x 86 The altitude is 86 or about 19.6. 11. Let x represent the altitude. 4 2 x x 42

x2 32 x 32 x 42 The altitude is 42 or about 5.7. 12. Let x represent the altitude. x 7 x 2 4 2 x 168 x 168 x 242 The altitude is 242 or about 13.0.

Page 767

DE (2 2)2 [4 (1)]2 2 2 (4) (3 ) 25 5 EF [4 (2)]2 ( 1 (4)] 2 2 2 (2) 3 13 DF (4 2)2 [1 (1)]2 2 2 (6) 0 36 6 By the converse of the Pythagorean Theorem, if the sum of the squares of the measures of two sides of a triangle equals the square of the measure of the longest side then the triangle is a right triangle.

Lesson 7-2

1. Use the Distance Formula to determine the lengths of the sides. d (x2 x1)2 (y2 y1)2 2 (2 DE (3 0) 1)2

32 12 10 Extra Practice

524

DF 2¬ DE2 EF 2 62¬ 52 (13 )2 36¬ 25 13 36¬ 38 Since the sum of the squares of two sides does not equal the square of the longest side, DEF is not a right triangle. 4. Use the Distance Formula to determine the lengths of the sides. d (x1 x2)2 (y1 y2)2

8. Since the measure of the longest side is 7, 7 must be c, and a and b are 2 and 5. a2 b2¬ c2 22 52¬ 72 4 25¬ 49 29¬ 49 Since 29 49, segments with these measures cannot form a right triangle. Therefore, they do not form a Pythagorean triple. 9. Since the measure of the longest side is 51, 51 must be c, and a and b are 24 and 45. a2 b2¬ c2 242 452¬ 512 576 2025¬ 2601 2601¬ 2601 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple. 26 10. Since the measure of the longest side is 3 , 26 1 5 must be c, and a and b are and . 3 3 3 a2 b2¬ c2

2 ( DE (5 1) 2 2)2 2 2 4 ( 4) 32 EF (2 5)2 [1 (2)]2 2 2 (7) 1 50 DF (2 1)2 (1 2)2 2 2 (3) (3 ) 18 By the converse of the Pythagorean Theorem, if the sum of the squares of the measures of two sides of a triangle equals the square of the measure of the longest side, then the triangle is a right triangle. EF 2¬ DE2 DF 2 (50 )2¬ (32 )2 (18 )2 50¬ 32 18 50¬ 50 Since the sum of the squares of two sides equals the square of the longest side, DEF is a right triangle. 5. Since the measure of the longest side is 2, 2 must be c, and a and b are both 1. a2 b2¬ c2 12 12¬ 22 1 1¬ 4 2¬ 4 Since 2 4, segments with these measures cannot form a right triangle. So, they do not form a Pythagorean triple. 6. Since the measure of the longest side is 35, 35 must be c, and a and b are 21 and 28. a2 b2¬ c2 212 282¬ 352 441 784¬ 1225 1225¬ 1225 These segments form the sides of a right triangle since they satisfy the Pythagorean Theorem. The measures are whole numbers and form a Pythagorean triple. 7. Since the measure of the longest side is 7, 7 must be c, and a and b are 3 and 5. a2 b2¬ c2 32 52¬ 72 9 25¬ 49 34¬ 49 Since 34 49, segments with these measures cannot form a right triangle. Therefore, they do not form a Pythagorean triple.

2

2 2 26 5 3 ¬ 3

13

2 5 26 1 9 9 ¬ 9 2 6 2 6 ¬ 9 9 2 6 2 6 Since 9 9 , segments with these measures

form a right triangle. However, the three numbers are not whole numbers. Therefore, they do not form a Pythagorean triple. 10 1 0 11. Since the measure of the longest side is 11 , 11 6 8 must be c, and a and b are 11 and 11 . a2 b2¬ c2 2

2

161

2

8 10 1 1 ¬ 11 3 6 6 4 10 0 121 121 ¬ 121

10 0 10 0 121 ¬ 121 10 0 10 0 Since 121 121 , segments with these measures

form a right triangle. However, the three numbers are not whole numbers. Therefore, they do not form a Pythagorean triple. 12. Since the measure of the longest side is 1, 1 must be c, and a and b are both 1 2. 2 2 2 a b ¬ c 2

12

2

2 1 2 ¬ 1

1 1¬ 1 4 4 1¬ 1 2 1, segments with these measures Since 1 2

cannot form a right triangle. Therefore, they do not form a Pythagorean triple.

525

Extra Practice

40 2 13. Since the measure of the longest side is , 15

21 35

40 6 2 10 must be c, and a and b are 15 3 and 5. 2

36

a2 b2¬ c2 2

3 5 or 0.60 adjacent leg

cosM hypotenuse

2

40 10 2 5 ¬ 15

a n

10 24 0 6 9 25 ¬ 225 24 0 24 0 225 ¬ 225 24 0 24 0 Since 225 225 , segments with these measures

28 35 4 5 or 0.80 opposite leg

tanM adjace nt leg

form a right triangle. However, the three numbers are not whole numbers. Therefore, they do not form a Pythagorean triple.

Page 767

m a 21 28 3 4 or 0.75

Lesson 7-3

opposite leg

sinA hypotenuse

1. Because the quadrilateral is a square, the two triangles are isosceles right triangles with angle measures 45, 45, and 90. Therefore, x 45. The length of the hypotenuse, 132 , is 2 times the length of a leg. So the leg length is 13 units and y 13. 2. In the 30°-60°-90° triangle, the shorter leg is x units long, the longer leg is y units long, and the hypotenuse is 25 units long. x 1 2 (25) or 12.5 3.

4.

5.

6.

a n 28 35 4 5 or 0.80 adjacent leg

cosA hypotenuse m n 21 35

y 3 (12.5) or 12.53 The triangle on the right is a 30°-60°-90° triangle with a hypotenuse of length 30 and with a shorter leg of length x. x 1 2 (30) or 15 The triangle on the left is an isosceles right triangle. y 2 x 2 (15) or 152 The two triangles are congruent, by SSS, so they are both 30°-60°-90° triangles. The shorter legs are 83 units long, the longer legs are y units long, and the hypotenuses are x units long. x 2(83 ) 163 y 3 (83 ) 24 The two triangles are congruent isosceles right triangles with legs of length x and hypotenuses of length y. x 1 ) 2 (1002 502 hypotenuse 2 x y 2 (502 ) 100 The two triangles are congruent 30°-60°-90° triangles. The shorter legs are y units long, the longer legs are x units long, and the hypotenuses are 123 units long. (123 y 1 ) 2 63 x 3 (63 ) 18

Page 767

3 5 or 0.60 opposite leg

tanA adjace nt leg a m 28 21 4 3 or about 1.33 opposite leg

2. sinM hypotenuse m n

2 5

10 5 or about 0.63 adjacent leg

cosM hypotenuse a n

3

5 15 or about 0.77 5 opposite leg tanM adjace nt leg m a 2 3 36 or about 0.82 opposite leg sinA hypotenuse a n 3

5 15 or about 0.77 5 adjacent leg cosA hypotenuse m n 2 5 10 or about 0.63 5

Lesson 7-4 opposite leg

1. sinM hypotenuse m n

Extra Practice

526

opposite leg

opposite leg

tanA adjace nt leg

sinA hypotenuse

a m

a n

3

5 3

2 6 2 or about 1.22 opposite leg 3. sinM hypotenuse m n

2 30

10 4 or about 0.79 adjacent leg

cosA hypotenuse m n

2 2

1

3 5

2 2 or about 0.71

6 4 or about 0.61

2 30

adjacent leg

cosM hypotenuse

opposite leg

tanA adjacent leg

a n

a m

2 2

1 2 2

5 3

35 15 3 or about 1.29

or about 0.71

opposite leg

tanM adjacent leg

5. Calculator keystrokes: 2nd [COS1] 0.6293 ENTER mA 51.00150333 The measure of A is about 51.0. 6. Calculator keystrokes: 2nd [SIN1] 0.5664 ENTER mB 34.49956639 The measure of B is about 34.5. 7. Calculator keystrokes: 2nd [TAN1] 0.2665 ENTER mC 14.92250149 The measure of C is about 14.9. 8. Calculator keystrokes: 2nd [SIN1] 0.9352 ENTER mD 69.26048039 The measure of D is about 69.3. 9. Calculator keystrokes: 2nd [TAN1] 0.0808 ENTER mM 4.619463489 The measure of M is about 4.6. 10. Calculator keystrokes: 2nd [COS1] 0.1097 ENTER mR 83.70197782 The measure of R is about 83.7.

m a

2 2 2 2

1.00 opposite leg

sinA hypotenuse a n

2

2 1

2 2 or about 0.71

adjacent leg

cosA hypotenuse m n

2

2 1

2 2 or about 0.71

opposite leg

tanA adjacent leg a m

2 2 2 2

1.00 opposite leg 4. sinM hypotenuse

70 11. cos25° x

m n 3 5 2 30 6 4 or about 0.61 adjacent leg cosM hypotenuse a n 5 3 2 30 10 4 or about 0.79 opposite leg tanM adjace nt leg m a 3 5 53 15 5 or about 0.77

70 x cos 25°

Use a calculator for find x. Keystrokes: 70 COS 25 ENTER x 77.23645433 x is about 77.2. 32 12. tanx° 40 0.8 x tan1 0.8 Use a calculator to find x. Keystrokes: 2nd [TAN1] 0.8 ENTER x 38.65980825 x is about 38.7. 13. sin55° 8x 8 sin55° x Use a calculator to find x. Keystrokes: 8 SIN 55 ENTER x 6.553216354 x is about 6.6.

527

Extra Practice

Page 768

4. Use the Law of Sines to write a proportion.

Lesson 7-5

A N sin sin a ¬ n sin 3 3° sin N 57.8 ¬ 43.2 43.2 si n 33° ¬ sinN 57.8 43.2 si n 33° sin1 ¬ N 57.8

1. Let x represent mRMN. RN tanx° M N 12 0 tanx° 450

12 0 x tan1 450

Use a calculator. x 14.9 The measure of the angle of elevation is about 14.9. 2. Let x represent LC. ROC and LCO are corresponding congruent angles, so mLCO 26. O L tan26° LC

Use a calculator. N 24° 5. We know the measures of two angles of the triangle. Use the Angle Sum Theorem to find mA. mA mK mX¬ 180 mA 33 62¬ 180 mA 95¬ 180 mA¬ 85 Since we know mA and a, use proportions A sin involving a . To find x: To find k:

75 tan26° x 75 x tan 26° Use a calculator. x 153.8 The distance from L to C is about 153.8 ft. 3. mKIS mASI 13. Let x represent SI.

A X sin sin a ¬ x sin 8 5° sin 62° x 28.5 ¬

K I cos13° SI 2000 cos13° x

xsin85°¬ 28.5sin62° 28.5 si n 62° x¬ sin 85°

200 0 x cos 1 3°

28.5 si n 33° k¬ sin 85°

X K sin sin x ¬ k sin55° sin K ¬ 3.6 3.7 3.6sin55° ¬ sinK 3.7 3.6sin55° ¬ K sin1 3.7

Lesson 7-6

1. Use the Law of Sines to write a proportion. A sin sin N a ¬ n sin 47° sin 3 2° a¬ 15

15sin47°¬ a sin32°

53°¬ K We know the measures of two angles of the triangle. Use the Angle Sum Theorem to find mA. mA mK mX 180 mA 53 55 180 mA 108 180 mA 72 Now use a proportion to find a.

15 sin 47° sin 32° ¬ a

Use a calculator. a 20.7 2. Use the Law of Sines to write a proportion. A N sin sin a ¬ n sin 7 5° sin 26° n 10.5 ¬

X sin sin A x ¬ a sin55° sin72° ¬ a 3.7

nsin75°¬ 10.5sin26° 10.5 si n 26° n¬ sin 75° Use a calculator. n 4.8 3. Use the Law of Sines to write a proportion. A N sin sin a ¬ n

asin55°¬ 3.7sin72° 3.7sin72°

a¬ sin55°

a¬ 4.3 Therefore, mK 53, mA 72, and a 4.3.

sin 6 5° sin N 20.5 ¬ 18.6 18.6 si n 65° ¬ sinN 20.5 18.6 s i n 65° 1 ¬ N sin 20.5

Use a calculator. N 55°

Extra Practice

ksin85°¬ 28.5sin33°

x¬ 25.3 k¬¬15.6 Therefore, mA 85, x 25.3, and k 15.6. 6. Since we know mX and x, use a proportion X sin involving x to find mK.

Use a calculator. x 2052.6 The distance from S to I is about 2052.6 ft.

Page 768

A K sin sin a ¬ k sin 8 5° sin 33° k 28.5 ¬

528

7. We know the measures of two angles of the triangle. Use the Angle Sum Theorem to find mX. mA mK mX¬ 180 65 35 mX¬ 180 100 mX¬ 180 mX¬ 80 Since we know mX and x, use proportions X sin involving x . To find a: To find k: X A sin sin x ¬ a sin 8 0° sin 65° a 50 ¬

X K sin sin x ¬ k sin 8 0° sin 35° k 50 ¬

asin80°¬ 50sin65°

ksin80°¬ 50sin35°

3.

5.1 9 D¬ cos1 9.6 D¬ 57.3° 4. e2¬ c2 d2 2cdcosE 81.32¬ 42.52 502 2(42.5)(50)cos E 6609.69¬ 1806.25 2500 4250cos E 2303.44¬ 4250cos E 2303 .44 4250 ¬ cosE

2303 .44 E¬ cos1 4250 E¬ 122.8° 5. We know the measures of two sides and the included angle, so we use the Law of Cosines. c2¬ a2 b2 2abcosC c2¬ 352 252 2(35)(25)cos55° c¬ 352 252 2(35) (25)co s 55° c¬ 29.1 Now find mA using the Law of Sines. C sin sin A c ¬ a

50 sin 65° 50 sin 35° a¬ k¬ sin 80° sin 80° a¬ 46.0 k¬ 29.1 Therefore, mX 80, a 46.0, and k 29.1.

8. We know the measures of two angles of the triangle. Use the Angle Sum Theorem to find mK. mA mK mX¬ 180 122 mK 15¬ 180 mK 137¬ 180 mK¬ 43 Since we know mA and a, use proportions A sin involving a . To find k: A sin sin K a ¬ k sin 1 22° sin 43° k 33.2 ¬

ksin122°¬ 33.2sin43°

sin 5 5° sin A 29.1 ¬ 35 35 sin 55° 29.1 ¬ sinA 35 sin 55° sin1 29.1 ¬ A

To find x:

80°¬ A Find mB the same way. C sin sin B c ¬ b

A sin sin X a ¬ x sin 1 22° sin 15° x 33.2 ¬

sin 5 5° sin B 29.1 ¬ 25 25 sin 55° 29.1 ¬ sinB 25 sin 55° sin1 29.1 ¬ B

x sin122°¬ 33.2sin15°

33.2 si n 43° k¬ sin 122°

33.2 si n 15° x¬ sin 122°

k¬ 26.7 x¬ 10.1 Therefore, mK 43, k 26.7, and x 10.1.

Page 768 1.

45°¬ B Therefore, c 29.1, mA 80, and mB 45. 6. We know an angle and the opposite side, so we use the Law of Sines. N O sin sin n ¬ o

Lesson 7-7

e2¬ c2 d2 2cdcosE 1502¬ 1002 1252 2(100)(125)cosE 22,500¬ 10,000 15,625 25,000cos E 3125¬ 25,000cos E

sin8 0° sin O 3.5 ¬ 1.7 1.7si n 80° ¬ sinO 3.5 1.7s i n 80° 1 ¬ O sin 3.5

315 25, 000 ¬ cosE

3125 E¬ cos1 25,0 00

2.

d2¬ c2 e2 2cecosD 3.52¬ 1.22 42 2(1.2)(4)cos D 12.25¬ 1.44 16 9.6cosD 5.19¬ 9.6cosD 5.1 9 9.6 ¬ cosD

E¬ 82.8° c2¬ d2 e2 2decosC 52¬ 62 92 2(6)(9)cos C 25¬ 36 81 108cos C 92¬ 108cos C 92 1 08 ¬ cosC

29°¬ O Use the Angle Sum Theorem to find mP. mN mO mP 180 80 29 mP ¬180 109 mP ¬180 mP ¬71 Find p using the Law of Sines. N P sin sin n ¬ p

92 C¬ cos1 10 8

C¬ 31.6°

sin 8 0° sin 71° p 3.5 ¬

psin80°¬ 3.5sin71° 3.5 si n 71° p¬ sin 80°

p¬ 3.4 Therefore, mO 29, mP 71, and p 3.4.

529

Extra Practice

7. We know all three sides and no angles, so we use the Law of Cosines. x2¬ b2 y2 2by cosX 752¬ 602 302 2(60)(30)cos X 5625¬ 3600 900 3600cos X 1125¬ 3600cos X 112 5 3600 ¬ cosX

5. Apply the Interior Angle Sum Theorem, using n 5a. S 180(n 2) 18 (5a 2) The sum of the measures of the interior angles is 180(5a 2). 6. Apply the Interior Angle Sum Theorem, using n b. S 180(n 2) 180(b 2) The sum of the measures of the interior angles is 180(b 2). 7. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S¬ 180(n 2) 156n¬ 180(n 2) 156n¬ 180n 360 0¬ 24n 360 360¬ 24n 15¬ n The polygon has 15 sides. 8. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S¬ 180(n 2) 168n¬ 180(n 2) 168n¬ 180n 360 0¬ 12n 360 360¬ 12n 30¬ n The polygon has 30 sides. 9. Use the Interior Angle Sum Theorem to write an equation to solve for n, the number of sides. S¬ 180(n 2) 162n¬ 180(n 2) 162n¬ 180n 360 0¬ 18n 360 360¬ 18n 20¬ n The polygon has 20 sides. 10. Since n 15, the sum of the measures of the interior angles is S 180(15 2) or 2340. Therefore, the measure of an interior angle is 234 0 15 or 156. For n 15, the measure of an exterior angle is 36 0 15 or 24.

112 5 X¬ cos1 4500

X¬ 108° Using the Law of Cosines again, y2¬ b2 x2 2bx cosY 302¬ 602 752 2(60)(75)cosY 900¬ 3600 5625 9000cos Y 8325¬ 9000cos Y 83 25 9000 ¬ cosY 832 5 Y¬ cos1 9000

Y¬ 22° Find the remaining angle using the Angle Sum Theorem. mB mX mY¬ 180 mB 108 22¬ 180 mB 130¬ 180 mB¬ 50 Therefore, mB 50, mX 108, and mY 22.

Page 769

Lesson 8-1

1. Apply the Interior Angle Sum Theorem, using n 25. S 180(n 2) 180(25 2) 4140 The sum of the measures of the interior angles 4140. 2. Apply the Interior Angle Sum Theorem, using n 30. S 180(n 2) 180(30 2) 5040 The sum of the measures of the interior angles 5040. 3. Apply the Interior Angle Sum Theorem, using n 22. S 180(n 2) 180(22 2) 3600 The sum of the measures of the interior angles 3600. 4. Apply the Interior Angle Sum Theorem, using n 17. S 180(n 2) 180(17 2) 2700 The sum of the measures of the interior angles 2700.

Extra Practice

is

is

11. Since n 13, the sum of the measures of the interior angles is S 180(13 2) or 1980. Therefore, the measure of an interior angle is 198 0 13 or about 152.3. For n 13, the measure of an exterior angle is 36 0 13 or about 27.7.

is

12. Since n 42, the sum of the measures of the 42 interior angles is S 180(42 2) or 7200. Therefore, the measure of an interior angle is 720 0 42 or about 171.4. For n 42, the measure of an exterior angle is 36 0 42 or about 8.6.

is

530

Page 769

15. Since BD bisects AC, AE EC. AE EC 6c 1 35 6c 36 c6 16. Since AB DC, AB DC. AB DC 3d 7 40 3d 33 d 11

Lesson 8-2

1. SRU UTS, because SRU and UTS are opposite angles, and opposite angles of a parallelogram are congruent. 2. UTS is supplementary to TSR and also to TUR. UTS and TSR are consecutive angles, and so are UTS and TUR. Consecutive angles of a parallelogram are supplementary. 3. R U S T , because R U and S T are opposite sides of RSTU, and opposite sides of a parallelogram are parallel (by definition). 4. R U S T , because R U and S T are opposite sides of RSTU, and opposite sides of a parallelogram are congruent. 5. RST TUR, by SSS: R U T S , R S T U , and T R T R . 6. S V V U , because the diagonals of a parallelogram bisect each other. 7. BAE and DCA are congruent, because they are alternate interior angles. Since mDCA 28, mBAE 28. 8. BCE and DAC are congruent, because they are alternate interior angles. Since mDAC 28, mBCE 28. 9. BEC forms a linear pair with BEA. mBEC mBEA 180 mBEC 91 180 mBEC 89 10. CED and BEA are vertical angles, and mBEA 91. So, mCED 91. 11. mAEB 91, and mBAE 28 (Exercise 7). mABE mAEB mBAE 180 mABE 91 28 180 mABE 119 180 mABE 61 12. First find mABC. Because opposite angles are congruent, mABC mADC. By the Angle Sum Theorem, mADC mDAC mDCA¬ 180 mADC 28 28¬ 180 mADC 56¬ 180 mADC¬ 124 So, mABC 124. By the Angle Addition Postulate, and using the information from Exercise 11, mABE mEBC mABC 61 mEBC 124 mEBC 63 13. Since B C A D , BC¬ AD. BC¬ AD 5a 9.4¬ 39.4 5a¬ 30 a¬ 6 14. Since AC bisects BD, BE ED. BE¬ ED 4b 2.8¬ 18.8 4b¬ 16 b¬ 4

Page 769

Lesson 8-3

1. No; only one pair of sides is shown to be parallel. 2. Yes; if the diagonals of a quadrilateral bisect each other, then the quadrilateral is a parallelogram. 3. Yes; if both pairs of opposite sides in a quadrilateral are parallel, then the quadrilateral is a parallelogram. 4. For the top and bottom sides to be parallel, alternate interior angles must be congruent. 6x 54 x9 By the same reasoning applied to the left and right sides, 3y 3 36 3y 39 y 13 So, x 9 and y 13. 5. Since opposite sides must be congruent, measures of opposite sides must be equal. x 5y¬ 2x y 3x 3y¬ 15 Solve the system of equations by substitution. Begin by solving the first equation for x. 5y y¬ x 2x 4y¬ x Now substitute in the second equation. 3(4y) 3y¬ 15 12y 3y¬ 15 15y¬ 15 y¬ 1 So, y 1 and x 4(1) or 4. 6. Since the diagonals of a parallelogram bisect each other, 3y 4 2y 10 3y 2y 4 10 y6 and 5x 2¬ 3x 4 5x 3x¬ 2 4 2x¬ 6 x¬ 3 So, x 3 and y 6.

531

Extra Practice

7.

y

L (3, 2)

T . Find the midpoint of R

4

x x

0 (2) 6 (3) 1 2 1 2 2, 2 2, 2

x

(1, 1.5) Since the diagonals bisect each other, QRST is a parallelogram.

2 4

2

2

4

y y

M (5, 2)

2

10.

I (10, 9)

y

4

6

H (13, 5) N (3, 6)

O (5, 6)

J (2, 4) 10

If the opposite sides of a quadrilateral are parallel, then it is a parallelogram.

2

G (5, 0)

2 2 M slope of L 5 (3) or 0

Since opposite sides have the same slope, M L O N and L O M N . Therefore, LMNO is a parallelogram.

W (5, 6) y

X (2, 5) 4

95 4 I slope of H 10 (13) or 3 40 4 slope of G J 2 (5) or 3

2 4

x

2

I and G H J have the same slope, so they are parallel. Since one pair of opposite sides is congruent and parallel, GHIJ is a parallelogram.

2

Z (8, 2) Y (3, 4)

4

Page 770

Use the Distance Formula to determine whether opposite sides are congruent. Start with W X and Y Z , which appear to be different lengths. WX [2 ( 5)]2 (5 6)2 2 (1) 7 2 or 50 2 ZY [3 (8)] [ 4 (2)] 2 2 2 5 ( 2) or 29 Since W X and X Y are not congruent, WXYZ is not a parallelogram. 9.

y 4

1SR¬ 1QT 2 2

2 4

2

T (2, 3)

2

SU¬ QU SU¬ 15 2. The diagonals of a rectangle are congruent and bisect each other. T Q ¬ R S QT¬ RS 1QT¬ 1RS 2 2 UT¬ RU x 9¬ 3x 6 x 3x¬ 9 6 2x¬ 15 x¬ 7.5

4 x

S (3, 1) 4

If the diagonals bisect each other, then the figure is a parallelogram. So the two diagonals must have the same point as their midpoint. Find the midpoint of Q S . x x

y y

5 3 4 (1) 1 2 1 2 2, 2 2, 2

(1, 1.5)

Extra Practice

Lesson 8-4

1. Because a rectangle is a parallelogram, diagonals T Q and S R bisect each other. QU UT 2x 3 4x 9 2x 4x 3 9 2x 12 x6 QU 2x 3 2(6) 3 15 The diagonals of a rectangle are congruent. R S ¬ QT SR¬ QT

R (0, 6) Q (5, 4)

x

First use the Distance Formula to determine whether opposite sides H I and G J are congruent. 2 2 HI [10 (13)] (9 5 ) 32 42 or 5 GJ [2 (5)]2 (4 0)2 32 42 or 5 Since HI GJ, H I G J . Next, use the Slope Formula to determine whether H I G J .

2 6 8 N slope of M 3 5 2 or 4

6

2 6

6 (6) N slope of O 3 (5) or 0 6 2 8 O slope of L 5 (3) 2 or 4

8.

2

532

3.

4.

5.

6.

7.

8. LM O N , so MLN ¬LNO. mMLN ¬mLNO m2 ¬m5 m2 ¬38 Use the following results as needed in Exercises 9–18. Because L O M N , L N M O , and O N O N , LON MNO. Then MON LNO, so m8 m5 38. Use the Angle Sum Theorem. m8 m5 m9 ¬180 38 38 m9 ¬180 76 m9 ¬180 m9 ¬104 Thus, m8 30 and m9 104. 9. 3 and 9 form a linear pair. Therefore, m3 m9 ¬180. m3 104 ¬180 m3 ¬76 10. 4 and 9 are vertical angles and are congruent. Since m9 ¬104, m4 104. 11. By the Angle Addition Theorem, mONL mLNM ¬mONM. m5 m6 ¬mONM Use the fact that m5 38 and that ONM is a right angle. 38 m6 ¬90 m6 ¬52 12. By the Angle Addition Theorem, mLOM mMON ¬mLON. m7 m8 ¬mLON Use the fact that m8 ¬38 and that LON is a right angle. m7 38 ¬90 m7 ¬52 13. m8 ¬38 14. m9 ¬104 15. 10 and 9 form a linear pair. Therefore, m10 m9 180. m10 104 ¬180 m10 ¬76 16. L M O N , so LMO ¬MON. mLMO ¬mMON m11 ¬m8 Since m8 ¬38, m11 38. 17. MNO is a right angle. So, MNO is a right triangle, and MON and OMN are complementary. mMON mOMN ¬90 m8 m12 ¬90 38 m12 ¬90 m12 ¬52 18. OLM is an angle of the rectangle, so mOLM 90.

So, RU 3x 6 3(7.5) 6 16.5 and RS 2RU 2(16.5) 33 A rectangle is a parallelogram, and opposite sides of a parallelogram are congruent. S Q ¬ R T QS¬ RT 3x 40¬ 16 3x 3x 3x¬ 40 16 6x¬ 24 x¬ 4 So QS 3x 40 3(4) 40 or 28. STR is a right angle, so mSTR 90. Use the Angle Addition Theorem. mSTQ mRTQ¬ mSTR 5x 3 3 x¬ 90 4x 6¬ 90 4x¬ 84 x¬ 21 R Q S T , so SRQ¬ RST. mSRQ¬ mRST x2 6¬ 36 x 2 x x 30¬ 0 (x 6)(x 5)¬ 0 x 6 0 or x 5 0 x 6 x5 RTS is a right angle. So, RTS is a right triangle, and SRT and RST are complementary. mSRT mRST 90 mSRT 36 x 90 mSRT 90 36 x mSRT 54 x Since x 6 or x 5, mSRT 54 (6) 48, or mSRT 54 5 59. QRT is a right angle. So, QRT is a right triangle, and QTR and TQR are complementary. mQTR mTQR ¬90 x 32 x2 16 ¬90 x2 x 48 ¬90 x2 x 42 ¬0 (x 7)(x 6) ¬0 x 7 ¬0 or x 6 ¬0 x ¬7 x ¬6 S Q R T , so TQS ¬QTR. mTQS ¬mQTR mTQS ¬x 32 mTQS 7 32 25 or mTQS 6 32 38 LON is a right angle. So, LON is a right triangle, and OLN and ONL are complementary. mOLN mONL ¬90 m1 38 ¬90 m1 ¬52

533

Extra Practice

Page 770

7. BY 10.5 (Exercise 5) 8. The diagonals bisect each other. AC 2(AY) AC 2(6) or 12

Lesson 8-5

1. RQ S T , so QRS and TSR are supplementary consecutive angles. mQRS mTSR 180 Substitute mTSR 40 for mQRS. mTSR 40 mTSR ¬180 2(mTSR) ¬220 mTSR ¬110 Because RST is bisected by S Q ,

Page 770 1a.

Lesson 8-6 y

D (2, 9)

A (0, 9)

mTSQ ¬1 2 (mTSR).

6

mTSQ ¬1 2 (110) or 55

2. From Exercise 1, mTSR 110. mQRS mTSR 40 mQRS 110 40 or 70 3. By the Angle Sum Theorem, mSRT mSTR mTSR 180. Because QRST is a rhombus, R S S T and so RST is an isosceles triangle, with SRT STR. mTSR 110 (Exercise 1) mSRT mSRT 110 ¬180 2(mSRT) ¬70 mSRT ¬35 4. Because a rhombus is a parallelogram, and because opposite sides of a parallelogram are congruent, Q R T S . QR TS QR 15 5. Because a rhombus is a parallelogram, and the diagonals of a parallelogram bisect each other, CY AY and DY BY. DY ¬BY 10r 4 3r 3 ¬ 2 3r 3 ¬5r 2 3 2 ¬3r 5r 5 ¬2r 2.5 ¬r Find BY and CY.

2

A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 9 9 slope of D A ¬ 0 ( 2) ¬0 2 or 0

4 4 slope of C B ¬ 3 ( 5) ¬0 8 or 0

94 D ¬ slope of C 2 (5) ¬5 3

4 9 slope of A B ¬ 30

5 5 ¬ 3 or 3

Exactly one pair of opposite sides is parallel, A D and C B . So, ABCD is a trapezoid. 1b. Use the Distance Formula to determine whether the legs are congruent. 2 (9 CD ¬ [2 (5)] 4)2 2 2 ¬ 3 5 ¬34 AB ¬ (3 0 )2 (4 9)2 ¬ 32 ( 5)2 ¬34 Since the legs are congruent, ABCD is an isosceles trapezoid. 2a. S (10, 7) R (4, 6)

10(2.5) 4 ¬ or 10.5 2 CY AY CY 6 Find mACB.

y

B Y tan(ACB) ¬ CY

Q (1, 4)

10 .5 ACB ¬tan1 6 mACB ¬60 6. First find mCBD. Because the diagonals of a rhombus are perpendicular, BYC is a right triangle with right angle BYC. CBY and BCY are complementary. BCY is the same angle as ACB. mCBY mBCY ¬90 mCBY mACB ¬90 mCBY 60 ¬90 mCBY ¬30 B D bisects ABC, so mABD mCBY. mABD 30

Extra Practice

4x

2

10r 4 BY ¬ 2

10 .5 tan(ACB) ¬ 6

B (3, 4)

C (5, 4)

T (1, 1) 2

4

6

8

x

A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 6 4 slope of Q R ¬ 41 ¬2 3

534

7 1 slope of T S ¬ 10 1

4a.

2 ¬6 9 or 3 1 4 slope of T Q ¬ 11 3 ¬ 0 or undefined 7 6 S ¬ slope of R 10 4 1 ¬6

4 2 2

1 (2) slope of W X ¬ 31 ¬1 2

2 (5) slope of Z Y ¬ 71 1 ¬3 6 or 2 2 (5) slope of Z W ¬ 11 ¬3 0 or undefined

2 (1) Y ¬ slope of X 73

1 1 ¬ 4 or 4 Exactly one pair of opposite sides is parallel, W X and Z Y . So, WXYZ is a trapezoid. 4b. Use the Distance Formula to determine whether the legs are congruent. 2 [ ZW ¬ (1 1) 2 ( 5)]2 2 2 ¬ 0 3 ¬ 9 or 3 XY ¬ (7 3 )2 [ 2 ( 1)]2 2 2 ¬ 4 ( 1) ¬ 17 Since the legs are not congruent, WXYZ is not an isosceles trapezoid. 5. E F is the median.

L (1, 2) x

M (4, 1)

2

Y (7, 2)

A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula.

O (3, 1) 2

X (3, 1)

Z (1, 5)

4

2

x 2

W (1, 2)

Exactly one pair of opposite sides is parallel, R Q and T S . So, QRST is a trapezoid. 2b. Use the Distance Formula to determine whether the legs are congruent. QT ¬ (1 1 )2 (4 1)2 2 2 ¬ 0 3 ¬ 32 or 3 RS ¬ (10 4)2 (7 6 )2 2 2 ¬ 6 1 ¬ 37 Since the legs are not congruent, QRST is not an isosceles trapezoid. 3a. y

4

y

4

N (3, 5) A quadrilateral is a trapezoid if exactly one pair of opposite sides is parallel. Use the Slope Formula. 5 1 slope of O N ¬ 3 ( 3)

6 ¬ 6 or 1

2 1 slope of L M ¬ 41

EF 1 2 (AB CD)

3 ¬ 3 or 1

13 1 2 (8 CD)

2 1 L ¬ slope of O 1 ( 3)

26 8 CD 18 CD 6. P Q is the median.

¬1 4

1 (5) slope of N M ¬ 43

PQ 1 2 (LM ON)

¬4 1 or 4

PQ 1 2 (21 17)

N Exactly one pair of opposite sides is parallel, O and L M . So, LMNO is a trapezoid. 3b. Use the Distance Formula to determine whether the legs are congruent. OL ¬ [1 ( 3)]2 (2 1)2 2 2 ¬ 4 1 ¬ 17 2 [ NM ¬ (4 3) 1 (5)] 2 ¬ 12 42 ¬ 17 Since the legs are congruent, LMNO is an isosceles trapezoid.

PQ 19 M L O N , so M and N are consecutive supplementary angles. mM mN ¬180 mM 96 ¬180 mM ¬84 Similarly, L and O are supplementary. mL mO ¬180 36 mO ¬180 mO ¬144

535

Extra Practice

7. The length of the median is given by

4. Given: EFGH is a quadrilateral. Prove: EFGH is a rhombus.

median 1 2 (QR TS) 1 median 2(12 24)

y

F(a 2, a 2) G(2a a

median 18 S and T are congruent. mS mT mS 52 R and S are consecutive angles. mR mS ¬180 mR 52 ¬180 mR ¬128 8. AB is the median of XYZW.

E(0, 0)

((2a a2 ) a )2 2 (a2 a2 )2 FG ¬ 2 2 ¬ (2a) 0 ¬ 4a2 or 2a

AB 1 2 (13 21) AB 17 is the median of XYBA. CD

((2a a2 ) 2a)2 (a 2 0)2 GH ¬ 2 2 ¬2a 2a ¬4a 2 or 2a

CD 1 2 (XY AB) CD 1 2 (13 17) CD 15

(2a 0)2 (0 0 )2 EH ¬ 2) ¬(2a 02 2 ¬4a or 2a EF FG GH EH EF F G G H E H Since all four sides are congruent, EFGH is a rhombus.

Lesson 8-7

1. Unequal sides of an isosceles trapezoid are parallel. Assuming that A D and B C are both vertical, the xcoordinate of D is a and the x-coordinate of C is a. Leg D C will have the same length as A B if the ycoordinate of C is b and the y-coordinate of D is c. So, the coordinates of C are (a, b) and the coordinates of D are (a, c). 2. On the assumption that all sides are vertical or horizontal and that the rectangle is symmetric about the y-axis: The x-coordinate of Q is the opposite of the x-coordinate of R, namely 3b, and the y-coordinate of Q is the same as the y-coordinate of R, namely a. Points T and S lie on the x-axis, so their y-coordinates must be 0. The x-coordinate of T is the same as the x-coordinate of Q, namely 3b. The x-coordinate of S is the same as the x-coordinate of R, namely 3b. The coordinates of S are (3b, 0), the coordinates of T are (3b, 0), and the coordinates of Q are (3b, a). y 3. Given: ABCD is a square. Prove: AC and BD are A(0, a) B(a, a) congruent.

Proof: 2 (0 AC ¬ (a 0) a)2 2 2 ¬ a a ¬ 2a2 2 (a BD ¬ (a 0) 0)2 2 2 ¬ a a ¬ 2a2 AC BD AC B D

Extra Practice

x

H(2a, 0)

Proof: EF ¬ (a2 0)2 (a 0)2 2 2 2 ¬ 2a 2a ¬ 4a2 or 2a

AB 1 2 (XY WZ)

Page 771

2, a 2)

Page 771

Lesson 9-1

1. To find the coordinates of each point of the image, for each point of the original triangle, multiply the y-coordinate by 1. A(2, 2) → A (2, 2) B(3, 2) → B (3, 2) N(3, 1) → N (3, 1) Plot the reflected vertices and connect them to form the image A B N . y

A

B

N O

x

N A

D(0, 0) C (a, 0) x

536

B

2. To find the coordinates of each point of the image, interchange the x-coordinate and the y-coordinate for each point of the original rectangle. B(3, 3) → B (3, 3) A(3, 4) → A (4, 3) R(1, 4) → R (4, 1) N(1, 3) → N (3, 1) Plot the reflected vertices and connect them to form the image B A R N . y

N

A

B

D y

H

F H

6. Use the vertical grid lines to find a corresponding point for each vertex so that the line y 1 is equidistant from each vertex and its image. Q(1, 3) → Q (1, 5) U(3, 1) → U (3, 3) A(1, 0) → A (1, 2) D(3, 4) → D (3, 6) Plot the reflected vertices and connect them to form the image Q U A D .

x

N xR

B

D

B

R

x

OF

O

y

B

A

3. To find the coordinates of each point of the image, for each point of the original trapezoid, multiply both coordinates by 1. Z(2, 3) → Z (2, 3) O(2, 4) → O (2, 4) I(3, 3) → I (3, 3) D(3, 1) → D (3, 1) Plot the reflected vertices and connect them to form the image Z O I D .

y

D

Q U A A

x

O 1

y

U

y

O

I

Q

Z

D

D

O

7. Use the horizontal grid lines to find a corresponding point for each vertex so that the line x 2 is equidistant from each vertex and its image. C(0, 4) → C (4, 4) A(1, 3) → A (5, 3) B(4, 0) → B (0, 0) Plot the reflected vertices and connect them to form the image C A B .

x

D

Z I O

4. To find the coordinates of each point of the image, for each point of the original triangle, multiply the x-coordinate by 1. P(2, 1) → P (2, 1) Q(2, 2) → Q (2, 2) R(3, 4) → R (3, 4) Plot the reflected vertices and connect them to form the image P Q R .

C y

C

B B

x

O

y

A

A x

P

P

2

O x

Q R

Page 771

Lesson 9-2

1.

Q R

5. To find the coordinates of each point of the image, for each point of the original square, multiply both coordinates by 1. B(4, 4) → B (4, 4) D(1, 4) → D (1, 4) F(1, 1) → F (1, 1) H(4, 1) → H (4, 1) Plot the reflected vertices and connect them to form the image B D F H .

c

d

Reflect the blue figure in line c, then reflect the resulting image in d to produce the red figure. The red figure is a translation image of the blue figure.

537

Extra Practice

2. Because the red and blue figures have different orientations, the red figure is not a translation image of the blue figure. 3. No; it is not one reflection after another with respect to the two parallel lines. 4. y L

7.

E A

B B

x

O

D

C

M O

This translation moved every point of the preimage 2 units left and 3 units up. A(1, 3) → A (1 2, 3 3) or A (1, 6) B(1, 1) → B (1 2, 1 3) or B (3, 4) C(1, 2) → C (1 2, 2 3) or C (3, 1) D(3, 2) → D (3 2, 2 3) or D (1, 1) E(3, 1) → E (3 2, 1 3) or E (1, 4) Plot the translated vertices and connect them to form pentagon A B C D E .

x

This translation moved each point of the preimage 2 units right and 1 unit up. L(2, 3) → L (2 2, 3 1) or L (4, 4) M(4, 1) → M (4 2, 1 1) or M (2, 2) Plot the translated vertices and connect them to form segment L M . 5.

E D

C

L

M

y

A

8. R

y

y

R D

E

T

O O

F E

x

x

D

S

T S

F

This translation moved every point of the preimage 3 units right and 2 units down. R(4, 3) → R (4 3, 3 2) or R (1, 1) S(2, 3) → S (2 3, 3 2) or S (1, 5) T(2, 1) → T (2 3, 1 2) or T (5, 3) Plot the translated vertices and connect them to form triangle R S T .

This translation moved every point of the preimage 1 unit left and 3 units down. D(1, 2) → D (1 1, 2 3) or D (0, 1) E(2, 1) → E (2 1, 1 3) or E (3, 2) F(3, 1) → F (3 1, 1 3) or F (4, 4) Plot the translated vertices and connect them to form triangle D E F . 6.

Page 772

X W

X

W x

O

Z Y Y

Z

This translation moved every point of the preimage 1 unit right and 1 unit down. W(1, 1) → W (1 1, 1 1) or W (2, 0) X(2, 3) → X (2 1, 3 1) or X (1, 2) Y(3, 2) → Y (3 1, 2 1) or Y (2, 3) Z(2, 2) → Z (2 1, 2 1) or Z (3, 3) Plot the translated vertices and connect them to form quadrilateral W X Y Z .

Extra Practice

Lesson 9-3

1. • First graph KLM. • Draw a segment from point P(1, 1) to point K(4, 2). • Use a protractor to measure a 90° angle counterclockwise with P K as one side. . • Draw PR • Use a compass to copy P K onto PR. Name the segment P K . • Repeat with points L and M. K L M is the image of KLM under a 90° counterclockwise rotation about the point P(1, 1).

y

R

K (2, 2)

y

L (1, 3) K (4, 2) M (2, 1) x

L (3, 1) M (1, 0)

538

P (1, 1)

2. • First graph FGH. • Draw a segment from point P(0, 0) to point F(3, 3). • Use a protractor to measure a 90° angle clockwise with P F as one side. • Draw PR. • Use a compass to copy P F onto PR. Name the segment P F . • Repeat with points G and H. F G H is the image of FGH under a 90° clockwise rotation about the point P(0, 0). R

F (3, 3)

5. First reflect QUA in the x-axis. Then label the image Q U A . Next, reflect the image in the line y x. The coordinates of the image are Q (4, 0), U (2, 3), and A (1, 1). The angle of rotation is 90° counterclockwise. y Q

yx

U Q

A

x

y

U

A U

Q

H (1, 1)

6. First reflect AEO in the line y x. Then label the image A E O . Next, reflect the image in the y-axis. The coordinates of the image are A (3, 5), E (1, 4), and O (2, 1). The angle of rotation is 90° clockwise. A E E A A O

x

G (4, 2) F (3, 3) H (1, 1)

G (2, 4)

3. First reflect HIJ in the x-axis. Then label the image H I J . Next, reflect the image in the y-axis. H I J is the image of HIJ under reflections in the x-axis and the y-axis. The coordinates of the image are H (2, 2), I (2, 1), and J (1, 2). The angle of rotation is 180°. y

I

E

J

H

I

x

H

J

I H

I

x

Page 772

H

180(6 2) or 120°, and each interior angle of a 6

square measures 90°. Find whole number values for h and t so that 120h 90t 360. Let h 1. 120(1) 90t ¬360 120 90t ¬360 90t ¬240 t ¬2.67 Let h 2. 120(2) 90t ¬360 240 90t ¬360 90t ¬120 t ¬1.33 Let h 3. 120(3) 90t ¬360 360 90t ¬360 90t ¬0 t ¬0 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from regular hexagons and squares.

x

N P

Lesson 9-4

1. No; Use the algebraic method to determine whether a semi-regular tessellation can be created using regular hexagons and squares of side length 1 unit. Each interior angle of a hexagon measures

N

P

x

y x

yx

N

O

O

J

4. First reflect NOP in the y-axis. Then label the image N O P . Next, reflect the image in the line y x. N O P is the image of NOP under reflections in the y-axis and the line y x. The coordinates of the image are N (1, 3), O (3, 5), and P (3, 2). The angle of rotation is 90° clockwise.

P

O

y

J

y

A

O

O

539

Extra Practice

2. No; Use the algebraic method to determine whether a semi-regular tessellation can be created using squares and regular pentagons of side length 1 unit. Each interior angle of a pentagon measures

7. Always; for a regular polygon to tessellate the plane, its interior angle measure must be a factor of 360. If the measure of an interior angle of a regular polygon is 120, three such polygons are required at each vertex. If the measure of an interior angle is greater than 120, the only possible whole number of polygons per vertex is two. These polygons would be required to have an interior angle measuring 180°, which is impossible. Therefore, if the measure of one interior angle of a regular polygon is greater than 120, it cannot tessellate the plane.

180(5 2) or 108°, and each interior angle of a 5

square measures 90°. Find whole number values for h and t so that 108h 90t 360. Let h 1. 108(1) 90t ¬360 108 90t ¬360 90t ¬252 t ¬2.8 Let h 2. 108(2) 90t ¬360 216 90t ¬360 90t ¬144 t ¬1.6 Let h 3. 108(3) 90t ¬360 324 90t ¬360 90t ¬36 t ¬0.4 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from squares and regular pentagons. 3. No; Use the algebraic method to determine whether a semi-regular tessellation can be created using regular hexagons and regular octagons of side length 1 unit. Each interior angle of a hexagon measures

Page 772

O M 1 3 (3)

O M 1 3. O M r(OM) 3 3(OM) 4 3 3(OM) 4 1 OM 4

4. O M r(OM) 7 O M 5 7 8

7 O M 5 7 8 O M 5 8

180(6 2) or 120°, and each interior angle of an 6 180(8 2) octagon measures 8 or 135°.

5. O M ¬r(OM) 4 ¬2 3 (OM)

Find whole number values for h and t so that 120h 135t 360. Let h 1. 120(1) 135t ¬360 120 135t ¬360 135t ¬240 t ¬1.78 Let h 2. 120(2) 135t ¬360 240 135t ¬360 135t ¬120 t ¬0.89 There are no more reasonable possibilities. So, a semi-regular tessellation cannot be created from regular hexagons and regular octagons. 4. Sometimes; some arrangements of isoceles right triangles will have the same combination of angles at each vertex, but some arrangements will not. 5. Always; semi-regular tessellations have the same combination of shapes and angles at each vertex like uniform tessellations. The shapes for semiregular tessellations are regular. 6. Sometimes; as long as the polygon that is not regular forms a pattern such that the sum of the measures of the angles at the different vertices is 360, the polygon tessellates the plane.

Extra Practice

Lesson 9-5

1. O M r(OM) O M 2(1) O M 2(1) O M 2 2. O M r(OM) O M 1 3 (3)

4 ¬2 3 (OM)

6 ¬OM 6. O M ¬r(OM) 3 ¬1.5(OM) 4

4.5 ¬1.5(OM) 3 ¬OM 7. Preimage Image (x, y) (3x, 3y) T(1, 1)

540

T (3, 3)

Image

13x, 13y

1 T 1 3, 3

R(1, 2)

2 R (3, 6) R 1 3, 3

I(2, 0)

I (6, 0)

I 2 3, 0

10.

y

R

R I

I

Image (3x, 3y)

T

B(1, 0)

B (3, 0)

x

D(2, 0)

D (6, 0)

F(3, 2)

F (9, 6)

H(0, 2)

H (0, 6)

T O

8. Image (3x, 3y)

E(2, 1)

E (6, 3)

1 E 2 3, 3

I(3, 3)

I (9, 9)

I (1, 1)

O(1, 2)

O (3, 6)

2 O 1 3, 3

13x, 13y

O

OB D

H

B

D x

F

H F

E

Page 773

Lesson 9-6

1. Find the magnitude. XY ¬(x x1)2 (y2 y1)2 2 2 ¬ (2 1) (3 1 )2 ¬ 13 ¬3.6 Graph XY to determine how to find the direction. Draw a right triangle that has XY as its hypotenuse and an acute angle at X.

x

I

2 D 3, 0 2 F 1, 3 2 H 0, 3 B 1 3, 0

y

E

O

13x, 13y

Image

Preimage (x, y)

y

Image

Preimage (x, y)

O

y

Y(2, 3)

I 9.

Preimage (x, y)

Image (3x, 3y)

A(0, 1)

A (0, 3)

B(1, 1)

B (3, 3)

C(0, 2)

C (0, 6)

D(1, 1)

D (3, 3)

X(1, 1)

Image

13x, 13y

x

1 B 1 3, 3 C 0, 2 3 1 D 1 3, 3 A 0, 1 3

y y x2 x1

2 1 tan X ¬

31 ¬ 2 1 ¬2 3

C D

B C D O A

mX ¬tan1 2 3 ¬33.7 A vector in standard position that is equal to XY forms a 33.7° angle with the negative x-axis in the second quadrant. So it forms a 180 33.7 or 146.3° angle with the positive x-axis. Thus, XY has a magnitude of about 3.6 units and a direction of about 146.3°.

y

B

x

A

541

Extra Practice

2. Find the magnitude. XY ¬ (x2 x1)2 (y2 y1)2

Thus, XY has a magnitude of about 7.6 units and a direction of about 293.2°. 4. Find the magnitude. XY ¬(x x1)2 (y2 y1)2 2 2 ¬ (4 2) (4 1)2 ¬ 61 ¬7.8 Graph XY to determine how to find the direction. Draw a right triangle that has XY as its hypotenuse and an acute angle at X.

¬ [2 ( 1)]2 [2 (1)]2 ¬18 ¬3 2 ¬4.2 Graph XY to determine how to find the direction. Draw a right triangle that has XY as its hypotenuse and an acute angle at X. y

y

Y(2, 2)

X(2, 1) x

X(1, 1)

x

y y x2 x1 2 ( 1) ¬ 2 (1) ¬3 3 or 1

Y(4, 4)

2 1 tan X ¬

y y x2 x1 4 1 ¬ 4 2 ¬5 6 mX ¬tan1 5 6

2 1 tan X ¬

mX ¬tan1(1) ¬45 A vector in standard position that is equal to XY forms a 45° angle with the positive x-axis in the first quadrant. Thus, XY has a magnitude of about 4.2 units and a direction of 45°. 3. Find the magnitude. XY ¬(x x1)2 (y2 y1)2 2 2 ¬ [2 (5)] ( 3 4)2 ¬ 58 ¬7.6 Graph XY to determine how to find the direction. Draw a right triangle that has XY as its hypotenuse and an acute angle at X. X(5, 4)

¬39.8 A vector in standard position that is equal to XY forms a 39.8° angle with the negative x-axis in the third quadrant. So it forms a 180 39.8 or 219.8° angle with the positive x-axis. Thus, XY has a magnitude of about 7.8 units and a direction of about 219.8°. 5. Find the magnitude. XY XY ¬(x x1)2 (y2 y1)2 2 2 ¬ [2 ( 2)] [2 (1)] 2 ¬ 17 ¬4.1 Graph XY to determine how to find the direction. Draw a right triangle that has XY as its hypotenuse and an acute angle at X.

y

y x

Y(2, 3)

Y(2, 2)

y y x2 x1 3 4 ¬ 2 (5) ¬7 3 mX ¬tan1 7 3

2 1 tan X ¬

y y x2 x1 2 (1) ¬ 2 (2) ¬1 4 mX ¬tan1 1 4

2 1 tan X ¬

¬66.8 A vector in standard position that is equal to XY forms a 66.8° angle with the positive x-axis in the fourth quadrant. So it forms a 360 66.8 or 293.2° angle with the positive x-axis. Extra Practice

x

X(2, 1)

¬14.0

542

8. First, graph RSTW. Next, translate each vertex by x , 3 units left and 4 units up. Connect the vertices to form quadrilateral R S T W .

A vector in standard position that is equal to XY forms a 14.0° angle with the positive x-axis in the fourth quadrant. So it forms a 360 14.0 or 346.0° angle with the positive x-axis. Thus, XY has a magnitude of about 4.1 units and a direction of about 346.0°. 6. Find the magnitude. XY XY ¬(x x1)2 (y2 y1)2 2 2 ¬ (3 3) [1 ( 1)]2 ¬ 40 ¬2 10 ¬6.3 Graph XY to determine how to find the direction. Draw a right triangle that has XY as its hypotenuse and an acute angle at X.

y

S R W T

S

R x

O

W T 9. First, graph AEIOU. Next, translate each vertex by b , 2 units left and 1 unit down. Connect the vertices to form pentagon A E I O U . y

A

y

E

A E

Y(3, 1)

I

x

I

U

x

O

X(3, 1)

O 10. c d 2, 3 3, 4 2 3, 3 4 5, 7 Find the magnitude, using initial point (0, 0) and endpoint (5, 7). c d ¬ (5 0 )2 (7 0)2 ¬ 74 ¬8.6 Graph the resultant to determine how to find the direction. Draw a right triangle.

y2 y1 tan X ¬ x2 x1 1) 1 ( ¬ 3 3 ¬1 3

mX ¬tan1 1 3 ¬18.4 A vector in standard position that is equal to XY forms an 18.4° angle with the negative x-axis in the second quadrant. So it forms a 180 18.4 or 161.6° angle with the positive x-axis. Thus, XY has a magnitude of about 6.3 units and a direction of about 161.6°. 7. First, graph HIJ. Next, translate each vertex by a, 1 unit right and 3 units up . Connect the vertices to form H I J . Y

(5, 7) y

x

O

y

H

I

7 0 tan ¬ 50

J

¬7 5

H I

O

U

O

¬tan1 75 ¬54.5° The vector forms a 54.5° angle with the positive x-axis. Thus, c d has a magnitude of about 8.6 units and a direction of about 54.5°.

J x

543

Extra Practice

11. a b 1, 3 4, 3 1 (4), 3 3 3, 6 Find the magnitude, using initial point (0, 0) and endpoint (3, 6). a b ¬ (3 0)2 (6 0 )2 ¬ 45 ¬3 5 ¬6.7 Graph the resultant to determine how to find the direction. Draw a right triangle.

13. s t ¬2, 5 6, 8 ¬2 (6), 5 (8) ¬4, 3 Find the magnitude, using initial point (0, 0) and endpoint (4, 3). s t ¬ (4 0)2 (3 0)2 ¬ 25 ¬5 Graph the resultant to determine how to find the direction. Draw a right triangle. y

y

(3, 6)

(4, 3)

x

O

3 0 tan ¬ 4 0

60 tan ¬ 3 0

¬3 4 ¬tan1 34 ¬36.9 The vector forms a 36.9° angle with the negative x-axis in the third quadrant. So it forms a 180 36.9 or 216.9° angle with the positive x-axis. Thus, s t has a magnitude of 5 units and a direction of about 216.9°. 14. m n ¬2, 3 2, 3 ¬2 (2), 3 3 ¬0, 0 The magnitude of the zero vector 0, 0 is 2 02 0 or 0. The direction is undefined. 15. u v ¬7, 2 4, 1 ¬7 4, 2 1 ¬3, 3 Find the magnitude, using initial point (0, 0) and endpoint (3, 3). u v ¬ (3 0)2 (3 0 )2 ¬ 18 ¬3 2 ¬4.2 Graph the resultant to determine how to find the direction. Draw a right triangle.

¬2 ¬tan1(2) ¬63.4° The vector forms a 63.4° angle with the negative x-axis in the second quadrant. So it forms a 180 63.4 or 116.6° angle with the positive x-axis. Thus, a b has a magnitude of about 6.7 units and a direction of about 116.6°. 12. x y ¬1, 2 4, 6 ¬1 4, 2 (6) ¬5, 4 Find the magnitude, using initial point (0, 0) and endpoint (5, 4). x y ¬ (5 0 )2 ( 4 0)2 ¬ 41 ¬6.4 Graph the resultant to determine how to find the direction. Draw a right triangle. y

x

O

x

O

y (3, 3) (5, 4)

0 4 tan ¬ 50

O

¬4 5 ¬tan1 45 ¬38.7° The vector forms a 38.7° angle with the positive x-axis in the fourth quadrant. So it forms a 360 38.7 or 321.3° angle with the positive x-axis. Thus, x y has a magnitude of about 6.4 units and a direction of about 321.3°.

Extra Practice

3 0 tan ¬ 3 0 ¬1 ¬tan1 (1) ¬45°

544

x

01

The vector forms a 45° angle with the negative x-axis in the second quadrant. So it forms a 180 45 or 135° angle with the positive x-axis. Thus, u v has a magnitude of about 4.2 units and a direction of 135°.

Page 773

Lesson 9-7

04

2 2 4 1 0 1 2 4 2 1 2 1 1 0 1 2 1 1 2 2 The coordinates of the vertices of the image are T (2, 2), R (1, 2), A (2, 1), and P (4, 1). 2. Write the ordered pairs as a vertex matrix. Then multiply the vertex matrix by the matrix for a 90° clockwise rotation about the origin (same as a 270° counterclockwise rotation).

0 1 2 2 1 0

Page 773

The coordinates of the vertices of the image are D (5, 10), E (5, 10), and F (10, 15). 6. Write the ordered pairs as a vertex matrix. Then multiply the vertex matrix by the reflection matrix for the x-axis. 1 0 3 6 5 3 6 5 0 1 4 2 3 4 2 3

0 3 3 2 2 4 4 4

22

4 2 4 4 2 0 3 3

Lesson 10-1

¬1 2 (34.2) or 17.1 ft C d (34.2) 34.2 or about 107.44 ft 3. C ¬d 12 ¬d 12 ¬d d ¬12 m r ¬1 2d

2 4 5 5 10 4 6 10 10 15

1. d 2r 2(18) or 36 in. C 2r 2(18) 36 or about 113.10 in. 2. r ¬1 2d

The coordinates of the vertices of the image are T (8, 8), R (4, 8), A (8, 4), and P (16, 4). 5. Write the ordered pairs as a vertex matrix. Perform the dilation by multiplying the vertex matrix by a scale factor of 2.5.

24

The coordinates of the vertices of the image are A (2, 2), B (4, 0), C (2, 3), D (4, 3), and E (4, 2).

The coordinates of the vertices of the image are T (6, 5), R (3, 5), A (2, 2), and P (8, 2). 4. Write the ordered pairs as a vertex matrix. Perform the dilation by multiplying the vertex matrix by a scale factor of 4. 1 2 4 2 8 4 8 16 4 2 8 8 4 2 1 1 4

2.5

4 1 6 4 7 6

01 10 22

The coordinates of the vertices of the image are J (3, 1), K (1, 4), L (2, 2), and M (3, 3). 10. Write the ordered pairs as a vertex matrix. Then multiply the vertex matrix by the reflection matrix for the line y x.

3 2 8 5 2 2

10

4 4 4 4 1 2 4 3 3 3 3 2 1 1

65

matrix by a scale factor of 1 2. 6 2 4 6 3 1 2 3 1 2 2 8 4 2 3 6 1 4

The coordinates of the vertices of the image are W (1, 0), X (4, 4), Y (1, 7), and Z (6, 6). 9. Write the ordered pairs as a vertex matrix. Perform the dilation by multiplying the vertex

The coordinates of the vertices of the image are T (2, 2), R (2, 1), A (1, 2), and P (1, 4). 3. Write the ordered pairs as a vertex matrix. Subtract 4 from each x-coordinate and add 3 to each y-coordinate by adding the translation matrix to the vertex matrix.

22

1 1 1 1 5 0 5 0 3 2 4 4 4 4

1 2 4 2 2 1 1 2 1 1 2 1 2 4

The coordinates of the vertices of the image are C (1, 1), D (5, 2), E (0, 2), and F (2, 1). 8. Write the ordered pairs as a vertex matrix. Add 1 to each x-coordinate and subtract 4 from each y-coordinate by adding the translation matrix to the vertex matrix.

1. Write the ordered pairs as a vertex matrix. Then multiply the vertex matrix by the reflection matrix for the x-axis.

1 1 2 2 1 1 5 0 2 0 1 2 2 1 1 5 0 2

¬1 2 (12) or 6 m 4. C ¬d 84.8 ¬d 84 .8 ¬d 26.99 ¬d d ¬26.99 mi r ¬1 2d

The coordinates of the vertices of the image are R (3, 4), S (6, 2), and T (5, 3). 7. Write the ordered pairs as a vertex matrix. Then multiply the vertex matrix by the matrix for a 90° counterclockwise rotation about the origin.

¬1 2 (26.99)

¬13.50 mi

545

Extra Practice

5. r ¬1 2d

Page 774

6.

7.

8.

9.

10.

C d (8.7) 8.7 or about 27.33 cm d 2r 2(3b) 6b in. C d (6b) 6b or about 18.85b in. The diameter of the circle is the same as the hypotenuse of the right triangle. Use the Pythagorean Theorem. a2 b2 ¬c2 62 82 ¬c2 100 ¬c2 10 ¬c So the diameter of the circle is 10 inches. C d C (10) or 10 The exact circumference is 10 inches. The diameter of the circle is the same as the hypotenuse of the right isosceles triangle. Use the Pythagorean Theorem. c2 ¬a2 b2 c2 ¬62 62 c2 ¬72 c ¬6 2 So the diameter of the circle is 6 2 centimeters. C d C (6 2 ) or 6 2 The exact circumference is 6 2 centimeters. The diameter of the circle is the same as the hypotenuse of the right isosceles triangle. Use the Pythagorean Theorem. c2 ¬a2 b2 c2 ¬122 122 c2 ¬288 c ¬12 2 So the diameter of the circle is 12 2 yards. C d C (12 2 ) or 12 2 The exact circumference is 12 2 yards. The diameter of the circle is the same as the hypotenuse of the right triangle. Use the Pythagorean Theorem. c2 ¬a2 b2 132 ¬212 c2 610 c2 610 c2 So the diameter of the circle is 610 meters. C d C ( 610 ) or 610 The exact circumference is 610 meters.

Extra Practice

Lesson 10-2

1. GKI and IKJ are a linear pair, and the angles of a linear pair are supplementary. mGKI mIKJ ¬180 mGKI 90 ¬180 mGKI ¬90 2. LKJ and HKG are vertical angles, and vertical angles are congruent. mLKJ mHKG mLKJ 23 3. From Exercise 1, mGKI 90. Use the Angle Addition Theorem. mGKH mHKI ¬mGKI 23 mHKI ¬90 mHKI ¬67 HKI and LKI are a linear pair, so mHKI mLKI ¬180 67 mLKI ¬180 mLKI ¬113 4. LKG and LKJ are a linear pair, and the angles of a linear pair are supplementary. mLKG mLKJ 180 From Exercise 2, mLKJ 23. mLKG 23 ¬180 mLKG ¬157 5. mHKI ¬67 (Exercise 3) 6. HKJ and LKG are vertical angles, and vertical angles are congruent. mHKJ mLKG From Exercise 4, mLKG 157. mHKJ 157 7. QXR is a right angle. mQXR mQR mQR 90 8. QW, WV, and QV are minor arcs, and QXV is a right angle. By the Arc Addition Postulate, mWV ¬mQV mQW mQW mWXV ¬mQXV 25 ¬90 mQW ¬65 mQW 9. TU, VU, and TV are minor arcs, and TXV is a right angle. By the Arc Addition Postulate, mVU ¬mTV mTU mTU mVXU mTXV 45 ¬90 mTU ¬45 mTU 10. WRV is a major arc. 360 mWV mWRV mWRV 360 mWXV 360 25 or 335 mWRV 11. SVW is a semicircle. mWV ¬mSVW mSV mSV mWXV ¬180 25 ¬180 mSV ¬155 mSV

¬1 2 (8.7) or 4.35 cm

546

12. TXV is a right angle. TV, WV, and TW are minor arcs. mTW ¬360 mTRW mTRW mTV mWV ¬360 90 25 ¬360 mTRW 115 ¬360 mTRW ¬245 mTRW

Page 774

3 is an inscribed angle that intercepts AB. mAB m3 ¬1 2 ¬1 2 (176) or 88 m1 m2 m3 ¬180 21 m2 88 ¬180 m2 109 ¬180 m2 ¬71 So m1 21, m2 71, and m3 88. . 2. First determine mWX mZW mWX ¬180 ¬180 120 mWX ¬60 mWX m3 mWX 60 Because 3 and 4 are vertical angles, m4 m3 60 Because AZY is isosceles, 5 6, and so m4 m5 m6 ¬180 60 2(m5) ¬180 2(m5) ¬120 m5 ¬60 ¬and m6 ¬60 Similarly, m1 60 and m2 60. So, m1 60, m2 60, m3 60, m4 60, m5 60, and m6 60. 3. 1 is an inscribed angle that intercepts TS. 1 m1 ¬ 2 mTS

Lesson 10-3

1. SI bisects H J , so HR 1 2 HJ. 1 HR 2HJ HR 1 2 (22) or 11 2. S I bisects H J , so RJ 1 2 HJ. 1 RJ 2HJ RJ 1 2 (22) or 11 3. S M bisects L G , so LT 1 2 LG. 1 LT 2LG LT 1 2 (18) or 9 4. S M bisects L G , so TG 1 2 LG. 1 TG 2 LG

5.

6.

7.

8.

9.

10.

TG 1 2 (18) or 9 2(mIJ ). I bisects S HJ, so mHJ mHJ 2(mIJ) 2(35) or 70 mHJ 2(mLM ). M S bisects LG, so mLG mLG 2(mLM) 2(30) or 60 mLG mLM . M S bisects LG, so mMG mMG mLM 30 mMG mIJ . I bisects S HJ, so mHI mHI mIJ 35 mHI B A and E D are equidistant from R, so A B E D . AB ED AB 30 Because R F E D , R F bisects E D . ED EF 1 2

¬1 2 (110) or 55 4 is an inscribed angle that intercepts TS. mTS m4 ¬1 2 ¬1 2 (110) or 55 3 is an inscribed angle that intercepts QR. 1 m3 ¬ 2 mQR ¬1 2 (40) or 20 6 is an inscribed angle that intercepts QR. mQR m6 ¬1 2 ¬1 2 (40) or 20 m1 m2 m3 ¬180 55 m2 20 ¬180 m2 75 ¬180 m2 ¬105 m4 m5 m6 ¬180 55 m5 20 ¬180 m5 75 ¬180 m5 ¬105 So m1 55, m2 105, m3 20, m4 55, m5 105, and m6 20.

EF 1 2 (30) or 15 11. Because R F E D , R F bisects E D . E F D 1 D 2 DF 1 2 (30) or 15 12. Because R C A B , R C bisects A B . BC 1 2 AB From Exercise 9, AB 30. BC 1 2 (30) or 15

Page 774

Lesson 10-4

1. 1 is an inscribed angle that intercepts BC. mBC m1 ¬1 2 ¬1 2 (42) or 21

547

Extra Practice

4. 1 is an inscribed angle that intercepts BC. mBC m1 ¬1 2

m4 m5 m6 ¬180 m4 56 28 ¬180 m4 84 ¬180 m4 ¬96 So, m1 96, m2 56, m3 28, m4 96 m5 56, and m6 28.

¬1 2 (70) or 35 7 is an inscribed angle that intercepts BC. 1 m7 ¬ 2 mBC

7.

¬1 2 (70) or 35 9 and 1 are alternate interior angles, and 7 and 3 are alternate interior angles. So m9 35 and m3 35. A, B, C, and D are right angles, so the numbered angles inside them are complementary pairs. Thus, m1 m11 ¬90 35 m11 ¬90 m11 ¬55. Similarly, m5 m6 m10 55. m1 m2 m3 ¬180 35 m2 35 ¬180 m2 70 ¬180 m2 ¬110 2 and 12 form a linear pair. m2 m12 ¬180 110 m12 ¬180 m12 ¬70 Because vertical angles are congruent, 8 2 and 4 12. So m8 110 and m4 70. So, m1 ¬35, m2 110, m3 ¬35, m4 70, m5 ¬55, m6 55, m7 ¬35, m8 110, m9 ¬35, m10 55, m11 ¬55, m12 70. 5. m1 ¬1 2 mTR

B D

A ABCD is a rhombus so AB BC CD AD. mBC mCD mAD , and Therefore, mAB mAB mBC mCD mAD 360. ¬360 Substituting, 4mBC mBC ¬90 and CD 90 ¬180. So mBC mCD So B D is a diameter of the circle. 8. R S

T

T is an inscribed angle that intercepts RS. 1 mT ¬ mRS 2 1 ¬ 2 (170) or 85

¬1 2 (100) or 50 1 m6 mTR

Page 775

2 1 ¬2(100) or 50

Lesson 10-5

1. First determine whether PON is a right triangle by using the Converse of the Pythagorean Theorem. (PO)2 (ON)2 ¬(PN)2 142 42 ¬(2 53)2 212 ¬212 Because the Converse of the Pythagorean Theorem is true, PON is a right triangle and PON is a right angle. Thus, P O O N , making O P a tangent to N. 2. First determine whether QRS is a right triangle by using the Converse of the Pythagorean Theorem. (QR)2 (RS)2 ¬(QS)2 62 182 ¬232 360 ¬529 Because the Converse of the Pythagorean Theorem is not true in this case, QRS is not a right triangle and QRS is not a right angle. So, S R is not tangent to Q.

R Q T , m3 90 and m4 90. Because S 1 and 2 are complementary, so m1 m2 ¬90 50 m2 ¬90 m2 ¬40 Similarly, m5 40. So m1 50, m2 40, m3 90, m4 90, m5 40, and m6 = 50. 6. m2 mXW m2 56 m5 mUV m5 56 m3 1mUY 2

m3 1 2 (56) or 28 1 m6 mXZ 2 m6 1 2 (56) or 28

m1 m2 m3 ¬180 m1 56 28 ¬180 m1 84 ¬180 m1 ¬96

Extra Practice

C

548

3. 8 x ¬(x 9) 2 8x ¬2x 18 6x ¬18 x ¬3 4. 15 r ¬9 5 15r ¬45 r ¬3 5. The vertical diameter bisects the horizontal chord. Each segment has length m. The diameter is divided into segments of length 3 and 11.

3. Because the radius is perpendicular to the tangent at the point of tangency, V U U T . This makes VUT a right angle and VUT a right triangle. Use the Pythagorean Theorem to find x. (VU)2 (UT)2 ¬(VT)2 x2 42 ¬52 x2 16 ¬25 x2 ¬9 x ¬3 Because x is the length of V U , ignore the negative result. Thus, x 3. 4. The radius is perpendicular to the tangent at the point of tangency, so the triangle is a right triangle. Use the Pythagorean Theorem to find x. 52 152 ¬x2 250 ¬x2 5 10 ¬x Because x is the length of the hypotenuse, ignore the negative result. Thus, x 5 10. 5. A B and B C are drawn from the same exterior point and are tangent to the circle, so A B B C . AB ¬BC 2x 1 ¬3x 7 1 ¬x 7 8 ¬x

Page 775

3

m 7

Lesson 10-6

¬1 2 (150) or 75 2. Find the measure of an angle that forms a linear pair with 6. If X is the angle that intercepts the 40° arc, mX 1 2 (40 35)

Page 776

Lesson 10-8

(x h)2 (y k)2 ¬r2 [x 1]2 [y (2)]2 ¬22 (x 1)2 (y 2)2 ¬4 2. The origin is the point (0, 0). (x h)2 (y k)2 ¬r2 (x 0)2 (y 0)2 ¬42 x2 y2 ¬16 3. (x h)2 (y k)2 ¬r2 2

[x (3)]2 [y (4)]2 ¬11

m7 ¬1 2 (220) or 110 4. x 1 2 (80 40)

4.

x 1 2 (40) or 20 15 ¬1 2 (80 2x) 15 ¬40 x 25 ¬x 25 ¬x

5.

x ¬1 2 (6x 40) x ¬3x 20 2x ¬20 x ¬10

6.

7.

Page 775

11

1.

¬1 2 (75) or 37.5 m6 180 mX 180 37.5 or 142.5 3. 360 140 ¬220

6.

m

m m ¬3 11 m2 ¬33 m ¬ 33 or about 5.7 6. The two segments that are tangent to the larger circle are congruent, and therefore each has a length of 6. In the smaller circle, we have a tangent and a secant. 5 (5 x) ¬62 25 5x ¬36 5x ¬11 x ¬2.2

1. m5 ¬1 2 (70 80)

5.

4

Lesson 10-7

1. x 8 ¬4 10 8x ¬40 x ¬5 2. 5 x ¬3 10 5x ¬30 x ¬6

8.

549

(x 3)2 (y 4)2 ¬11 If d 6, r 3. (x h)2 (y k)2 ¬r2 [x 3]2 [y (1)]2 ¬32 (x 3)2 (y 1)2 ¬9 (x h)2 (y k)2 ¬r2 (x 6)2 (y 12)2 ¬72 (x 6)2 (y 12)2 ¬49 If d 8, r 4. (x h)2 (y k)2 ¬r2 (x 4)2 (y 0)2 ¬42 (x 4)2 y2 ¬16 If d 22, r 11. (x h)2 (y k)2 ¬r2 [x 6]2 [y (6)]2 ¬112 (x 6)2 (y 6)2 ¬121 If d 2, r 1. (x h)2 (y k)2 ¬r2 [x (5)]2 [y 1]2 ¬12 (x 5)2 (y 1)2 ¬1

Extra Practice

9. Write the equation in standard form. (x 0)2 (y 0)2 52 The center is at (0, 0), and the radius is 5. Draw a circle with radius 5, centered at the origin.

Page 776

y

x

O

10. Write the x2 y2 4 equation in standard form. (x 0)2 (y 0)2 22 The center is at (0, 0), and the radius is 2. Draw a circle with radius 2, centered at the origin. y

x

O

Lesson 11-1

1. Base and Side: Each pair of opposite sides of a parallelogram has the same measure. Each base is 15 inches long, and each side is 20 inches long. Perimeter: The perimeter of a polygon is the sum of the measures of its sides. So, the perimeter of the parallelogram is 2(15) 2(20) or 70 in. Height: Use a 30°-60°-90° triangle to find the height. Recall that if the measure of the leg opposite the 30° angle is x, then the length of the hypotenuse is 2x, and the length of the leg opposite the 60° angle is x 3. 20 2x 10 x So, the height of the parallelogram is x 3 or 10 3 in. Area: A ¬bh ¬15(10 3) ¬150 3 or about 259.8 The area is about 259.8 in2 and the perimeter is 70 in. 2. Base and Side: Each pair of opposite sides of a parallelogram has the same measure. Each base is 28 ft long, and each side is 9 ft long. Perimeter: The perimeter of the parallelogram is 2(28) 2(9) 74 ft. Height: Use a 45°-45°-90° triangle to find the height. 9 ¬x 2 2 9 ¬x

11. Write the equation in standard form. (x 3)2 [y (1)]2 32 The center is at (3, 1), and the radius is 3. Draw a circle with radius 3, centered at (3, 1).

2

So, the height of the parallelogram is x or 2 9 ft.

y

2

Area: A ¬bh

2 9 ¬28 2

¬1262 or about 178.2 The area is about 178.2 ft2 and the perimeter is 74 ft. 3. Area: For a rectangle, A w 18.3(6.2) 113.5 Perimeter: The perimeter is 2(18.3) 2(6.2) 49. The perimeter is 49 m and the area is about 113.5 m2. 4. To determine the shape, first graph each point and draw the quadrilateral. Then determine the slope of each side.

x

O (3, 1)

12. Write the equation in standard form. (x 1)2 (y 4)2 12 The center is at (1, 4), and the radius is 1. Draw a circle with radius 1, centered at (1, 4). y (1, 4)

y O

Q (3, 3)

x

T (3, 1)

R (1, 3)

S (1, 1) x

Extra Practice

550

33 slope of Q R ¬ 1 (3)

6. To determine the shape, first graph each point and draw the quadrilateral. Then determine the slope of each side.

¬0 2 or 0

31 Q ¬ slope of T 3 (3)

N (9, 7) y

¬2 0 , which is undefined 11 S ¬ slope of T 1 (3) 0 ¬2 or 0 31 R ¬ slope of S 1 (1) , which is undefined ¬2 0

O (6, 7)

L (5, 3)

M (8, 3) x

Opposite sides have the same slope, so they are parallel. QRST is a parallelogram. All sides are vertical or horizontal, so the parallelogram is a rectangle. All sides have length 2 so they are congruent. So the rectangle is a square. A s2 22 4 5. To determine the shape, first graph each point and draw the quadrilateral. Then determine the slope of each side.

3 3 slope of L M ¬ 85 ¬0 3 or 0

7 3 O ¬ slope of L 65

¬4 1 or 4

7 7 N ¬ slope of O 96

¬0 3 or 0

7 3 N ¬ slope of M 98

y

¬4 1 or 4

Opposite sides have the same slope, so they are parallel. LMNO is a parallelogram. The slopes of the consecutive sides are not negative reciprocals of each other, so the sides are not perpendicular. Thus, the parallelogram is neither a square nor a rectangle. Find the area by first determining the base and height. Base: L M is parallel to the x-axis, so subtract the x-coordinates of the endpoints to find the length: LM 8 5 or 3. Height: L M and O N are horizontal segments, the distance between them, or the height, can be measured on any vertical segment. Reading from the graph, the height is 4. A bh 3(4) 12 The area of LMNO is 12 units2.

x

D(7, 3) C(2, 3)

A(7, 6)

B(2, 6)

6 (6) slope of A B ¬ 2 (7) ¬0 5 or 0

3 (6) D ¬ slope of A 7 (7) ¬3 0 , which is undefined

3 (3) slope of D C ¬ 2 (7) ¬0 5 or 0

3 (6) C ¬ slope of B 2 (2) ¬3 0 , which is undefined

Opposite sides have the same slope, so they are parallel. ABCD is a parallelogram. All sides are vertical or horizontal, so the parallelogram is a rectangle. However, not all sides are congruent, so the rectangle is not a square. Find the area by first determining the length and width. Length: A B is parallel to the x-axis, so subtract the x-coordinates of the endpoints to find the length: AB 2 (7) or 5. Width: A D is parallel to the y-axis, so subtract the y-coordinates of the endpoints to find the width: AD 3 (6) or 3. A w 5(3) 15 The area of ABCD is 15 units2.

551

Extra Practice

3. The quadrilateral is a rectangle so A w and w 18. Use the properties of 30°-60°-90° triangles to find the measure of . is the measure of the longer leg of the triangle whose shorter leg has measure 3. 18. So 18 A w (18 3)(18) 324 3 or about 561.2 The area of the rectangle is approximately 561.2 units2. 4. y B (2, 3) C (4, 3)

7. To determine the shape, first graph each point and draw the quadrilateral. Then determine the slope of each side. y

X (1, 1) Y (2, 1) x

W (1, 2)

Z (2, 2)

2 (2) slope of W Z ¬ 2 (1) ¬0 3 or 0

A (1, 1)

1 ( 2) X ¬ slope of W 1 (1)

D (7, 1) x

¬3 0 , which is undefined

1 1 Y ¬ slope of X 2 (1) ¬0 3 or 0

Base: Since A D and B C are horizontal, find their lengths by subtracting the x-coordinates of their endpoints. b1 AD 7 1 6 or 6 b2 BC 4 2 2 or 2 Height: Because the bases are horizontal segments, the distance between them can be measured on a vertical line. Subtract the y-coordinates. h 3 1 or 2

2) 1 ( Y ¬ slope of Z 22 ¬3 0 , which is undefined

Opposite sides have the same slope, so they are parallel. WXYZ is a parallelogram. All sides are horizontal or vertical, so the parallelogram is a rectangle. All sides have length 3 so they are congruent. So the rectangle is a square. A s2 32 9 The area of WXYZ is 9 units2.

Page 776

Area: A ¬1 2 h(b1 b2) ¬1 2 (2)(6 2)

Lesson 11-2

¬8 The area of trapezoid ABCD is 8 units2.

1. The area of the quadrilateral is the sum of the areas of the upper triangular portion and the lower triangular portion. For each of those two portions, the base measures 15 12 9 or 36 units. area ¬top area bottom area

5.

y

A (2, 2)

1 ¬1 2 bh1 2 bh2

x

1 ¬1 2 (36)(15) 2 (36)(9)

¬432 The area of the quadrilateral is 432 units2. 2. The altitude h of the parallelogram forms a 30°-60°-90° triangle in which the hypotenuse has measure 18 and the altitude is the longer leg. Use this fact to find the height of the trapezoid. 2x 18 x9 The height is x 3 or 9 3. Now find the area of the trapezoid.

D (4, 3)

C (7, 3)

Base: Since A B and D C are horizontal, find their lengths by subtracting the x-coordinates of their endpoints. b1 AB 2 (2) 4 or 4 b2 DC 7 (4) 11 or 11 Height: Because the bases are horizontal segments, the distance between them can be measured on a vertical line. Subtract the y-coordinates. h 2 (3) or 5

A ¬1 2 h(b1 b2) ¬1 )(25 13) 2 (93

¬1713 or about 296.2 The area of the trapezoid is approximately 296.2 units2. Extra Practice

B (2, 2)

552

Area: A ¬1 2 h(b1 b2)

8.

y

¬1 2 (5)(4 11)

¬37.5 The area of trapezoid ABCD is 37.5 units2. 6.

L (3, 0) x

O (7, 2)

C (8, 5)

D (1, 5) y

M (1, 2) N (3, 4)

A (1, 1)

B (4, 1)

Explore: To find the area of the rhombus, we need to know the length of each diagonal. Plan: Use coordinate geometry to find the length of each diagonal. Use the formula to find the area of rhombus LMNO. Solve: Let OM be d1 and LN be d2. Subtract the x-coordinates of O and M to find that d1 is 8. Subtract the y-coordinates of L and N to find that d2 is 4.

x

B and D C are horizontal, find their Base: Since A lengths by subtracting the x-coordinates of their endpoints. b1 AB 4 1 3 or 3 b2 DC 8 1 7 or 7 Height: Because the bases are horizontal segments, the distance between them can be measured on a vertical line. Subtract the y-coordinates. h 5 (1) or 6

A ¬1 2 d1d2 ¬1 2 (8)(4) or 16 The area of rhombus LMNO is 16 units2. Examine: The rhombus is made up of two congruent triangles with base O M . Each triangle has base 8 and height 2. So the area of the

9.

¬1 2 (6)(3 7)

¬30 The area of trapezoid ABCD is 30 units2. 7.

1 rhombus 2 2 8 2 16.

Area: A ¬1 2 h(b1 b2)

N (3, 6)

M (4, 2)

y

O (2, 2)

y x

A (2, 2)

B (4, 2) L (3, 2) x

Explore: To find the area of the rhombus, we need to know the length of each diagonal. Plan: Use coordinate geometry to find the length of each diagonal. Use the formula to find the area of rhombus LMNO. Solve: Let MO be d1 and NL be d2. Subtract the x-coordinates of M and O to find that d1 is 2. Subtract the y-coordinates of N and L to find that d2 is 8.

C (3, 2)

D (1, 2)

Base: Since D C and A B are horizontal, find their lengths by subtracting the x-coordinates of their endpoints. b1 DC 3 1 2 or 2 b2 AB 4 (2) 6 or 6 Height: Because the bases are horizontal segments, the distance between them can be measured on a vertical line. Subtract the y-coordinates. h 2 (2) or 4

A ¬1 2 d1d2 ¬1 2 (2)(8) or 8 The area of rhombus LMNO is 8 units2. Examine: The rhombus is made up of two congruent triangles with base M O . Each triangle has base 2 and height 4.

Area: A ¬1 2 h(b1 b2)

So the area of the rhombus 2 1 2 2 4 8.

¬1 2 (4)(2 6)

¬16 The area of trapezoid ABCD is 16 units2.

553

Extra Practice

10.

N (1, 12)

Page 777

y

8 4

O (5, 4)

M (3, 4) x 8

4

L (1, 4) Explore: To find the area of the rhombus, we need to know the length of each diagonal. Plan: Use coordinate geometry to find the length of each diagonal. Use the formula to find the area of rhombus LMNO. Solve: Let OM be d1 and NL be d2. Subtract the x-coordinates of O and M to find that d1 is 8. Subtract the y-coordinates of N and L to find that d2 is 16.

60

In a 30°-60°-90° triangle, when the side opposite the 30° angle is x units long, the side opposite the 60° angle is x3 units long. The height of the or 4.53 in. equilateral triangle is x3 A ¬1 2 bh ¬1 ) 2 (9)(4.53

¬20.253 or about 35.1 The area of the triangle is approximately 35.1 in2.


3.

y

B

M (4, 4) 4 L (2, 2) 8

4

x 4

4 8

8

A D C

N (10, 2)

Apothem: The central angles of a regular octagon are all congruent. Therefore, the measure of each 36 0 D is an apothem of the angle is 8 or 45. B octagon. It bisects ABC and is a perpendicular bisector of A C . So, mABD 1 2 (45°) 22.5°. Since AC 6, AD 3. Write a trigonometric ratio to find the length of B D .

O (4, 8)

Explore: To find the area of the rhombus, we need to know the length of each diagonal. Plan: Use coordinate geometry to find the length of each diagonal. Use the formula to find the area of rhombus LMNO. Solve: Let LN be d1 and MO be d2. Subtract the x-coordinates of L and N to find that d1 is 12. Subtract the y-coordinates of M and O to find that d2 is 12.

AD tan ABD ¬ BD 3 tan 22.5° ¬ BD

(BD)tan 22.5° ¬3 3 BD ¬ tan 22.5°

A ¬1 2 d1d2

BD ¬7.24 Area: The perimeter is 8(6) or 48 ft.

¬1 2 (12)(12) or 72 The area of rhombus LMNO is 72 units2. Examine: The rhombus is made up of two congruent triangles with base L N . Each triangle has base 12 and height 6.

A ¬1 2 Pa ¬1 2 (48)(7.24)

¬173.8 So, the area of the octagon is about 173.8 ft2.


Extra Practice

4.5

4.5

¬1 2 (8)(16) or 64 The area of rhombus LMNO is 64 units2. Examine: The rhombus is made up of two congruent triangles with base O M . Each triangle has base 8 and height 8.

8

9

9

A ¬1 2 d1d2

11.

Lesson 11-3

1. When the side length of a square is s, the perimeter is 4s. 4s ¬P 4s ¬54 s ¬13.5 Now find the area. A ¬s2 ¬(13.5)2 ¬182.25 or about 182.3 The area of the square is approximately 182.3 ft2. 2.

554

4.

6. The area of the shaded region is the difference between the area of the rectangle and the area of the circle. Since the diameter of the circle is 6, the radius is 3. shaded area ¬area of rectangle area of circle ¬w r2 ¬15(6) (3)2 ¬90 9 or about 61.7 To the nearest tenth, the area of the shaded region is 61.7 ft2. 7.

B

A D C Perimeter: The central angles of a regular decagon are all congruent. Therefore, the measure 36 0 of each angle is D is an apothem 10 or 36. B of the decagon. It bisects ABC and is a perpendicular bisector of A C . So, mABD 1(36) 18. Write a trigonometric ratio to find the 2

B

length of A D . AD tan ABD ¬ BD

AD tan 18° ¬ 22 22 tan 18° ¬AD 7.148 ¬AD Then AC 2(7.148) or 14.296, and the perimeter is about 10(14.296) or 142.96 centimeters.

D A

¬1 2 (142.96)(22)

¬1572.6 So, the area of the decagon is about 1572.6 cm2. 5. D

E

60

B

C

The area of the shaded region is the difference between the area of the circle and the area of the pentagon. First, find the area of the circle. A ¬r2 ¬(7)2 ¬153.9 To find the area of the pentagon, find the apothem and the perimeter. Apothem: The central angles of a regular pentagon are all congruent. Therefore, the 36 0 D is an measure of each angle is 5 or 72. B apothem of the pentagon. It bisects ABC and is a perpendicular bisector of A C . So, mABD (72) 36. Write a trigonometric ratio to find 1 2 the length of B D . B D cosABD ¬ AB

Area: A ¬1 2 Pa

6 cm

A

7 in .

C

The area of the shaded region is the difference between the area of the circle and the area of ECD. First, find the area of the circle. A r2 (6)2 113.1 To find the area of the triangle, use properties of 30°-60°-90° triangles. The hypotenuse of ABC is 6, so BC, the longer leg, is 3 3. Since EC 2(BC), EC 6 3. Next, find the height of ECD, DB. Since mDCB is 60, DB 3BC 33 3 or 9. Use the formula to find the area of the triangle. A ¬1 2 bh

BD cos36° ¬ 7 7cos36° ¬BD 5.6631 ¬BD Perimeter: Write a trigonometric ratio to find the length of A D . AD sinABD ¬ AB AD sin36° ¬ 7 7sin36° ¬AD 4.1145 ¬AD AC 2(AD) 8.229, and the perimeter is 5(AC) 5(8.229) or 41.145. Area: A ¬1 2 Pa

¬1 2 (41.145)(5.6631) ¬116.5 To the nearest tenth, the area of the shaded region is 153.9 116.5 or 37.4 in2.

¬1 )(9) 2 (63 ¬46.8 To the nearest tenth, the area of the shaded region is 113.1 46.8 or 66.3 cm2.

555

Extra Practice

Page 777

5. First, separate the figure into regions. Draw an auxiliary segment from B to D. This divides the figure into ABD and BCD.

Lesson 11-4

1. The figure can be separated into a semicircle with a radius of 3.5 units and a rectangle with dimensions 7 units by 24 units. area of irregular figure area of semicircle area of rectangle 2 ¬1 2 r w

y

h2

B (3, 0)

2 ¬1 2 (3.5) 7(24) ¬6.125 168 ¬187.2 To the nearest tenth, the area of the irregular figure is 187.2 units2. 2. The figure can be separated into a rectangle with dimensions 20 units by 15 units and a triangle with a base that measures 15 15 or 30 units and a height of 8 units. area of irregular figure area of rectangle area of triangle w 1 2 bh

x

C (2, 1)

h1

D (2, 3)

A (5, 3)

by For ABD, find the length of base AD subtracting the x-coordinates of A and D. Find the height by subtracting the y-coordinates. For by subtracting BCD, find the length of base CD the y-coordinates of C and D. Find the height by subtracting the x-coordinates. area of ABCD ¬area of ABD area of BCD 1 ¬1 2 b1h1 2 b2h2 1 ¬1 2 (7)(3) 2 (2)(5) ¬15.5 The area of quadrilateral ABCD is 15.5 units2. 6. First, separate the figure into regions. Draw an auxiliary segment from L to O. This divides the figure into LOP and trapezoid LMNO.

20(15) 1 2 (30)(8) 420 The area of the irregular figure is 420 units2. 3. The figure can be separated into a rectangle with dimensions 4 units by 16 units, a triangle with a base that measures 4 units and a height of 25 16 or 9 units, and a semicircle with a radius of 2 units. area of irregular figure area of rectangle area of triangle area of semicircle 1 2 w 1 2 bh 2 r

L (1, 4) y M (3, 2)

P (3, 1)

h1

2 1 4(16) 1 2 (4)(9) 2 (2)

h2 x

82 2 88.3 To the nearest tenth, the area of the irregular figure is 88.3 units2. 4. The figure is a triangle with base S T . Subtract the y-coordinates of S and T to find ST 3 0 or 3. The height of the triangle is 3.

O (1, 2)

N (3, 1)

by For triangle LOP, find the length of base LO subtracting the y-coordinates of L and O. Find the height by subtracting the x-coordinates. For trapezoid LMNO, find the lengths of the bases by subtracting the y-coordinates. Find the height by subtracting the x-coordinates. area of LMNOP area of LOP area of trapezoid LMNO

R (0, 5) y

S (3, 3)

1 1 2 bh1 2 h1(b1 b2) 1 1 2 (6)(2) 2 (4)(6 3)

T (3, 0) x

24 The area of LMNOP is 24 units2.

Page 777

A ¬1 2 bh 1 ¬2(3)(3) ¬4.5 The area is 4.5 units2.

Extra Practice

Lesson 11-5

1. Use the formula to find the total area of the sectors. N 2 A ¬ r 360

36 36 2 ¬ 360 (10 ) ¬20 ¬62.8 in2 To find the probability, divide the area of the sector by the area of the circle. The area of the circle is r2, and r ¬10.

556

area of sector P(orange) ¬ area of circle 20 ¬ 2

5. Area of the shaded region: The area of the shaded region is the area of the hexagon minus the area of the circle.

10

¬1 5 or 0.20 The probability that a random point is in the orange sectors is 0.20. 2. Use the formula to find the total area of the sectors.

180(6 2)

1 mBAD 1 6 2 mEAD 2 1 ¬2(120) 60 For the area of the hexagon, find the apothem and perimeter.

N 2 A ¬ r 360

40 60 2 ¬ 360 (10 )

25 0 ¬ 9 ¬87.3 in2 To find the probability, divide the area of the sector by the area of the circle. The area of the circle is r2, and r ¬10.

B

E

26

13 60

area of sector P(blue) ¬ area of circle

A

D

C

The apothem is 1 2 (26) or 13. Using properties of

25 0 9

¬ 102

, so 30°-60°-90° triangles, if AD x, BD x3 x 3 ¬13

25 ¬ 90 or about 0.28 The probability that a random point is in the blue sectors is about 0.28. 3. Use the formula to find the total area of the sectors.

13 3 x ¬ 3

13 3 26 3 Then AD 3 , AC 3 , and the perimeter

26 3 . is 6 3 or 523

N 2 A ¬ r 360 110 80 2 ¬ 360 (10 )

A ¬1 2 Pa 1 ¬2(523 )(13) ¬338 3 The radius of the circle is 13, so area of shaded region area of hexagon area of circle 338 3 (132) 338 3 169 54.5 units2 Probability: shaded area P(shaded) ¬ area of hexagon

47 5 ¬ 9 ¬165.8 in2 To find the probability, divide the area of the sector by the area of the circle. The area of the circle is r2, and r ¬10. area of sector P(green) ¬ area of circle 47 5

9 ¬ 102

19 ¬ 36 or about 0.53 The probability that a random point is in the green sectors is about 0.53. 4. Area of the shaded region: The area of the shaded region is the area of the large circle minus the area of the small circle, where the radii are r1 100 units and r2 50 units. area of shaded region area of large circle area of small circle r12 r22 (1002) (502) 7500 23,561.9 units2 Area of the square: The square is 80 50 100 50 80 or 360 units across. A ¬s2 ¬3602 ¬129,600 units2 Probability:

54.5 338 3

¬ ¬0.09 The probability that a random point is in the shaded region is about 0.09. 6. Area of shaded region: The area of the shaded region is the area of the triangle minus the areas of the two circles. Area of triangle: b ¬16 2 15 h ¬3 5 5 13 1

A ¬2bh 1 ¬2 (16 215 )(13) ¬154.4 units2 Area of circles (3)2 (5)2 ¬(32 52) ¬34 units2 Area of shaded region ¬154.4 34 units2 ¬47.6 units2 Probability: shaded area P(shaded) ¬ area of tri angle

shaded area P(shaded) ¬ area of square 750 0 ¬ 129,600

47.6

¬ 154.4

¬0.18 The probability that a random point is in the shaded region is about 0.18.

¬0.31 The probability that a random point is in the shaded region is about 0.31.

557

Extra Practice

Page 778

5. Use rectangular dot paper to draw a net. Let one unit on the dot paper represent 1 unit of length.

Lesson 12-1

1.

corner view

back view

2.

corner view

To find the surface area of the prism, add the areas of the rectangles. There are two 2-by-3 rectangles, two 2-by-6 rectangles, and two 3-by-6 rectangles. Surface area ¬2(2 3) 2(2 6) 2(3 6) ¬12 24 36 or 72 The surface area of the rectangular prism is 72 units2. 6. Use rectangular dot paper to draw a net. Let one unit on the dot paper represent 1 unit of length.

back view

3. The base is a pentagon, and the four faces meet in a point. So this solid is a pentagonal pyramid. Base: pentagon OXNEP Faces: OXNEP, PET, ETN, NTX, XTO, OTP Edges: P E , E N , N X , X O , O P , T P , T E , T N , T X , T O Vertices: T, P, E, N, X, O 4. This solid has a circle for a base and a vertex. So it is a cone. Base: circle L Vertex: Z 5. There are two octagon-shaped bases, and the other faces are parallelograms. So this solid is an octagonal prism. Bases: ABCDEFGH, STUVWXYZ Faces: ABCDEFGH, STUVWXYZ, ABXY, BCWX, CDVW, DEUV, FEUT, GFTS, HGSZ, HAYZ Edges: A B , B C , C D , D E , E F , F G , G H , A H , S T , T U , V U , V W , W X , X Y , Y Z , Z S , A Y , B X , C W , D V , E U , T F , G S , H Z Vertices: A, B, C, D, E, F, G, H, S, T, U, V, W, X, Y, Z

Page 778

To find the surface area of the pyramid, add the areas of the base and the areas of the other faces. The base is a 2-by-2 square, and each of the other four faces is a triangle with a base measuring 2 units and a height of 2 units. Surface area ¬22 41 2 2 2 ¬4 8 or 12 The surface area of the square pyramid is 12 units2. 7. We need to know the length of the large rectangular upper surface. Use the Pythagorean Theorem. 32 42 ¬2 9 16 ¬2 25 ¬2 5 ¬ Use rectangular dot paper to draw a net. Let one unit on the dot paper represent 1 unit of length.

Lesson 12-2

1.

2.

3.

To find the surface area of the solid, add the areas of the rectangular and triangular surfaces. The base is a 2-by-4 rectangle, the vertical face is a 2-by-3 rectangle, the top is a 2-by-5 rectangle, and each of the two triangular sides has base length 4 and height 3. Surface area ¬2 4 2 3 2 5 21 2 4 3 ¬8 6 10 12 or 36 The surface area of the solid is 36 units2.

4.

Extra Practice

558

Page 778

Find the surface area. T ¬L 2B ¬94.64 2(2.6)(6.5) ¬128.44 The surface area is about 128.4 units2. 5. First, find the measure of the third side of the triangular base. c2 ¬a2 b2 302 ¬182 b2 900 ¬324 b2 576 ¬b2 24 ¬b The perimeter is 18 30 24 or 72 units. Find the lateral area. L ¬Ph ¬(72)(26) ¬1872 The lateral area is 1872 units2. Find the surface area. T ¬L 2B ¬1872 2 1 2 (24 18) ¬2304 The surface area is 2304 units2. 6. First, find c and the height h.

Lesson 12-3

1. The base is a 7-by-5 rectangle, so the perimeter is 2(7) 2(5) or 24 units. Find the lateral area. L ¬Ph ¬(24)(4) ¬96 The lateral area is 96 units2. Find the surface area. T ¬L 2B ¬96 2(7 5) ¬166 The surface area is 166 units2. 2. First, find c. C c

4 3

4

B 3

4

8 D A Use the Pythagorean Theorem. c2 ¬a2 b2 c2 ¬42 32 c2 ¬25 c ¬5 The perimeter of base ABCD is 5 8 3 4 or 20 units. Find the lateral area. L ¬Ph ¬(20)(9) ¬180 The lateral area is 180 units2. Find the surface area. T ¬L 2B ¬180 2 1 2 (3)(4 8)

15

h

c 15

15

45

30

Because the triangle is a 45°-45°-90° triangle, h 15 and c 152 . So the perimeter is 30 15 15 152 or 60 152. Find the lateral area. L ¬Ph ¬(60 15 2)(42) ¬2520 630 2 ¬3411.0 The lateral area is about 3411.0 units2. Find the surface area. T ¬L 2B ¬(2520 630 2) 2 1 2 (15)(30 15)

¬216 The surface area is 216 units2. 3. First, find the measure of the third side of the triangular base. c2 ¬a2 b2 c2 ¬62 82 c2 ¬100 c ¬10 The perimeter, then, is 10 6 8 or 24 units. Find the lateral area. L ¬Ph ¬(24)(9) ¬216 The lateral area is 216 units2. Find the surface area. T ¬L 2B ¬216 2 1 2 (6 8)

¬3195 6302 ¬4086.0 The surface area is about 4086.0 units2. 7. Find the hypotenuse of the base using the Pythagorean Theorem. c2 ¬a2 b2 c2 ¬62 82 c2 ¬100 c ¬10 The perimeter is 6 8 10 24 in. T ¬L 2B T ¬Ph 2B 228 ¬24h 2 1 2 (8 6) 228 ¬24h 48 180 ¬24h 7.5 ¬h The height of the prism is 7.5 in.

¬264 The surface area is 264 units2. 4. The base is a 2.6-by-6.5 rectangle, so the perimeter is 2(2.6) 2(6.5) or 18.2 units. Find the lateral area. L ¬Ph ¬(18.2)(5.2) ¬94.64 The lateral area is about 94.6 units2.

559

Extra Practice

8. Let x be the measure of the other leg of the triangular base. The perimeter of the base is 15 25 x or 40 x. The area of the base is 21 15 x. T ¬L 2B T ¬Ph 2B 1380 ¬(40 x) 18 2 1 2 15 x

8. The radius of the base and the height of the cylinder are given. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(16.5)(16.5) 2(16.5)2 ¬3421.2 The surface area is approximately 3421.2 m2.

1380 ¬720 18x 15x 660 ¬33x 20 ¬x The length of the other leg of the base is 20 in.

Page 779

Page 779

¬1 2 (28)(9) 49

Lesson 12-4

1. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(2)(3.5) 2(2)2 ¬69.1 The surface area is approximately 69.1 ft2. 2. If d 15 in., r 7.5 in. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(7.5)(20) 2(7.5)2 ¬1295.9 The surface area is approximately 1295.9 in2. 3. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(3.7)(6.2) 2(3.7)2 ¬230.2 The surface area is approximately 230.2 m2. 4. If d 19 mm, r 9.5 mm. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(9.5)(32) 2(9.5)2 ¬2477.1 The surface area is approximately 2477.1 mm2. 5. The radius of the base and the height of the cylinder are given. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(1.5)(4) 2(1.5)2 ¬51.8 The surface area is approximately 51.8 in2. 6. The diameter of the base and the height of the cylinder are given. If d 14 ft, r 7 ft. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(7)(32.5) 2(7)2 ¬1737.3 The surface area is approximately 1737.3 ft2. 7. The diameter of the base and the height of the cylinder are given. If d 1 in., r 0.5 in. Substitute values in the formula for surface area. T ¬2rh 2r2 ¬2(0.5)(10.5) 2(0.5)2 ¬34.6 The surface area is approximately 34.6 in2.

Extra Practice

Lesson 12-5

1. The slant height is 9 cm. The perimeter of the base is 4(7) or 28 cm, and the area of the base is 72 or 49 cm2. T ¬1 2 P B ¬175 The surface area is 175 cm2. 2. Find the perimeter and area of the base.

30

10.5

36 0° The central angle of the hexagon measures 6 or 60°. Let a represent the measure of the angle formed by a radius and the apothem. Then, 60 a 2 or 30. In a 30°-60°-90° triangle, if the side opposite the 30° angle has a length of x, 10 .5 the other leg has a length of x 3. Here, x 2

5.25, so the length of the apothem is 5.253 . Next, find the perimeter and area of the base. P ¬6s ¬6(10.5) or 63 B ¬1 2 Pa 1 ¬2(63)(5.253 )

¬165.3753 Finally, find the surface area. T ¬1 2 P + B ¬1 2 (63)(18) 165.3753 ¬853.4 The surface area is approximately 853.4 in2.

560

¬253 Find the surface area of the pyramid. T ¬1 2 P B

3. Find the perimeter and area of the base.

¬ 36

a 22

11

36 0° The central angle of the pentagon measures 5 or 72°. Let represent the measure of the angle formed by a radius and the apothem. Then, 2 72 or 36. Use trigonometry to find the length of the apothem. 11 tan36° ¬ a 11 a ¬ tan 36° ¬15.14 Next, find the perimeter and area of the base. P ¬5s ¬5(22) or 110 B ¬1 2 Pa

¬1 ) 253 2 (30)(102 ¬255.4 The surface area is approximately 255.4 cm2. 5. To find the surface area, first find the length of the sides of the base. A right triangle is formed by the slant height, the edge with length 17, and half the side of the base. Let a be one-half the side length of the base. c2 ¬a2 b2 172 ¬a2 152 289 ¬a2 225 64 ¬a2 8 ¬a So the side length of the base is 2(8) or 16 ft, and the perimeter is 4(16) or 64 ft. Find the surface area. T ¬1 2 P B 2 ¬1 2 (64)(15) 16

¬736 The surface area is 736 ft2.1 2 6. Each side, including the base, is an equilateral triangle of side length 3 centimeters. The altitude of this triangle is 3 1 3. Find the 2 (3), or 1.5 area of a side.

¬1 2 (110)(15.14)

¬832.7 Finally, find the surface area. T ¬1 2 P B ¬1 2 (110)(40) 832.7

A ¬1 2 bh ¬1 ) 2 (3)(1.53 ¬2.25 3 Find the total area. T ¬4A ¬4(2.25 3) ¬9 3 or about 15.6 The surface area is approximately 15.6 cm2.

¬3032.7 The surface area is approximately 3032.7 m2. 4. To find the surface area, first find the slant height of the pyramid. The slant height is the altitude of a triangle with base of 10 and sides of 15.

Page 779 15

15

5

Lesson 12-6

1. Use the Pythagorean Theorem to find the slant height, . 2 ¬a2 b2 2 ¬62 102 2 ¬136 ¬11.66 Now use the formula for the surface area. T ¬r r2 ¬(6)(11.66) (6)2 ¬332.9 The surface area is approximately 332.9 in2. 2. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 342 ¬r2 302 1156 ¬r2 900 256 ¬r2 16 ¬r Now use the formula for the surface area. T ¬r r2 ¬(16)(34) (16)2 ¬2513.3 The surface area is approximately 2513.3 ft2.

5

Since the triangle is isosceles, the altitude bisects the base. Use the Pythagorean Theorem to find . c2 ¬a2 b2 152 ¬52 2 225 ¬25 2 200 ¬2 10 2 ¬ The base is an equilateral triangle. Its perimeter is 3(10) or 30 cm. Its altitude is 3 times half the side length, or 5 3 cm. B ¬1 2 bh ¬1 ) 2 (10)(53

561

Extra Practice

3. For an isosceles right triangle, the length of the hypotenuse is 2 times the leg length. 17 2 Now use the formula for the surface area. T ¬r r2 ¬(17)(17 2) (17)2 ¬2191.9 The surface area is approximately 2191.9 cm2. 4. Use the Pythagorean Theorem to find the slant height, . 2 ¬a2 b2 2 ¬(2.2)2 (10.5)2 2 ¬115.09 ¬10.728 Now use the formula for the surface area. T ¬r r2 ¬(2.2)(10.728) (2.2)2 ¬89.4 The surface area is approximately 89.4 in2. 5. Use the formula for the surface area. T ¬r r2 ¬(6.25)(7.0) (6.25)2 ¬260.2 The surface area is approximately 260.2 cm2. 6. Use the Pythagorean Theorem to find the slant height, . 2 ¬a2 b2 2 ¬302 82 2 ¬964 ¬31.0483 Now use the formula for the surface area. T ¬r r2 ¬(30)(31.0483) (30)2 ¬5753.7 The surface area is approximately 5753.7 ft2. 7. Use the Pythagorean Theorem to find the radius. c2 ¬a2 b2 402 ¬282 r2 1600 ¬784 r2 816 ¬r2 28.5657 ¬r Now use the formula for the surface area. T ¬r r2 ¬(28.5657)(40) (28.5657)2 ¬6153.2 The surface area is approximately 6153.2 in2. 8. Use the Pythagorean Theorem to find the slant height, . 2 ¬a2 b2 2 ¬(7.5)2 (2.5)2 2 ¬62.5 ¬7.906 Now use the formula for the surface area. T ¬r r2 ¬(2.5)(7.906) (2.5)2 ¬81.7 The surface area is approximately 81.7 cm2.

Page 780

Lesson 12-7

1. Use the formula for the surface area of a sphere. T ¬4r2 ¬4(120)2 ¬180,955.7 The surface area is approximately 180,955.7 ft2. 2. If d 42.5 m, then r 21.25 m. Use the formula for the surface area of a sphere. T ¬4r2 ¬4(21.25)2 ¬5674.5 The surface area is approximately 5674.5 m2. 3. If d 2520 mi, then r 1260 mi. Use the formula for the surface area of a sphere. T ¬4r2 ¬4(1260)2 ¬19,950,370.0 The surface area is approximately 19,950,370.0 mi2. 4. Use the formula for the surface area of a sphere. T ¬4r2 ¬4(33)2 ¬13,684.8 The surface area is approximately 13,684.8 cm2. 5. First, find the radius of the hemisphere. C ¬2r 14.1 ¬2r 14 .1 2 ¬r To find the surface area, find half the surface area of the sphere and add the area of the great circle. 2 2 surface area ¬1 2 (4r ) r 14 .1 2 14 .1 2 ¬1 2 [4( 2 ) ] ( 2 ) ¬47.5 The surface area is approximately 47.5 cm2. 6. First, find the radius of the sphere. C ¬2r 50.3 ¬2r 50 .3 2 ¬r 8.0055 ¬r Now find the surface area of the sphere. T ¬4r2 ¬4(8.0055)2 ¬805.4 The surface area is approximately 805.4 in2. 7. Use the formula for the surface area of a sphere, and note that r2 is the area of a great circle. T ¬4r2 ¬4(98.5) ¬394 The surface area of the sphere is 394 m2. 8. First, find the radius of the hemisphere. C ¬2r 3.1 ¬2r 3. 1 2 ¬r 0.4934 ¬r To find the surface area, find half the surface area of the sphere and add the area of the great circle. 2 2 surface area ¬1 2 (4r ) r 2 2 ¬1 2 [4(0.4934) ] (0.4934) ¬2.3 The surface area is approximately 2.3 in2.

Extra Practice

562

9. Find half the surface area of the sphere and add the area of the great circle, noting that r2 is the area of the great circle. 2 2 surface area ¬1 2 (4r ) r

Page 780

1. V ¬1 3 Bh 2 ¬1 3 (5) (7.5) ¬62.5 The volume of the pyramid is 62.5 ft3.

¬1 2 [4(31,415.9)] 31,415.9 ¬94,247.7 The surface area is 94,247.7 ft2.

Page 780

Lesson 13-2

2 2. V ¬1 3 r h 1 ¬3(10)2(40) ¬4188.8 The volume of the cone is approximately 4188.8 mm3. 3. First, use the Pythagorean Theorem to find the missing leg length on the base, which is a right triangle. a2 b2 ¬c2 82 b2 ¬172 64 b2 ¬289 b2 ¬225 b ¬15 Now find the volume. V ¬1 3 Bh

Lesson 13-1

1. V ¬Bh ¬(52.5)(79.4)(102.3) ¬426,437.6 The volume is approximately 426,437.6 m3. 2. The diameter of the base, the diagonal, and the lateral edge of the cylinder form a right triangle. Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 h2 162 ¬302 h2 256 ¬900 h2 ¬644 h ¬ 644 Now find the volume. V ¬r2h ¬(8)2( 644 ) ¬5102.4 The volume is approximately 5102.4 ft3. 3. V¬¬Bh ¬1 2 (10)(20 7)(16) ¬2160 The volume is 2160 in3. 4. The solid is a rectangular prism with another rectangular prism removed from the inside. volume of solid initial volume volume of removed prism B1h B2h (10)2(10) (5)2(10) 750 The volume is 750 in3. 5. The solid is a cylinder with a rectangular prism removed from it. The square base of the rectangular prism has a diagonal of 9 2, so the side length of the base is 9. volume of solid volume of cylinder volume of removed prism r2h Bh (4.5 2)2(21) (9)2(21) 970.9 The volume is approximately 970.9 cm3. 6. The solid is a rectangular prism with another rectangular prism removed from it. volume of solid ¬initial volume removed volume ¬B1h B2h ¬(15)2(8) (9)(6)(8) ¬1368 The volume is 1368 in3.

1 ¬1 3 2 (8 15)(12)

¬240 The volume of the pyramid is 240 in3. 4. Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 52 h2 ¬132 25 h2 ¬169 h2 ¬144 h ¬12 Now find the volume. 2 V ¬1 3 r h 2 ¬1 3 (2.5) (12) ¬78.5 The volume is approximately 78.5 m3. 5. Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 62 h2 ¬122 36 h2 ¬144 h2 ¬108 h ¬10.39 Now find the volume. V ¬1 3 Bh

¬1 3 (10)(6)(10.39) ¬207.8 The volume is approximately 207.8 m3. 6. Because the height, the radius, and the slant height form a 45°-45°-90° triangle, the height and 1 radius each equal . 2 1 V ¬3r2h

12 12

¬1 3

2


563

Extra Practice

Page 781

3. Find the ratios of the corresponding parts.

Lesson 13-3

short dimension of right prism 31 short dimension of left prism ¬ 16

3 1. V ¬4 3 r 3 ¬4 3 (44 )

¬1.9375

¬356,817.9 ft3 2. First find the radius of the sphere. C ¬2r 4 ¬2r 2 ¬r Now find the volume. 3 V ¬4 3 r

long dimension of right prism 4 3 long dimension of left prism ¬ 18

¬2.3889 Since the ratios are not the same, the prisms are neither similar nor congruent. 4. Use the Pythagorean Theorem to find the height of the cone on the right. a2 b2 ¬c2 62 h2 ¬102 36 h2 ¬100 h2 ¬64 h ¬8 The two cones have the same radius and height, so they are the same shape and size. The cones are congruent. 5. In the cylinder on the right, the diameter, the height, and the diagonal form a right triangle. Use the Pythagorean Theorem to find the height. 302 h2¬¬342 h2¬¬256 h¬¬16 Since the cylinder on the right has a diameter of 30, it has a radius of 15. Both cylinders have the same radius and the same height. The cylinders are congruent. 6. Find the ratios of the corresponding parts.

3

2 ¬4 3 ¬1.1 m3 3. The volume of a hemisphere is one-half the volume of a sphere. 4 3 V ¬1 2 3 r 3 ¬2 3 (17 ) ¬10,289.8 mm3 3 4. V ¬4 3 r

3 ¬4 3 (1.5) ¬14.1 cm3 5. The volume of a hemisphere is one-half the volume of a sphere. 4 3 V ¬1 2 3 r

¬2 )3 3 (72 ¬2031.9 m3 6. The volume of a hemisphere is one-half the volume of a sphere. 4 3 V ¬1 2 3 r

20 side of larger base side of smaller base ¬ 5 2

¬22

3 ¬2 3 (45) ¬190,851.8 ft3

32 larger height smaller height ¬ 8 2

¬2 2 The ratios of the measures are equal, so the prisms are similar. Since the scale factor is not 1, the solids are not congruent.

3 7. V ¬4 3 r 3 ¬4 3 (0.5) 3 ¬0.5 in

Page 781

Lesson 13-4

Page 781

1. The two spheres have the same shape but different sizes. They are similar. 2. Find the ratios of the corresponding parts.

Lesson 13-5

1. • Plot the x-coordinate first. Draw a segment from the origin 3 units in the positive direction. • To plot the y-coordinate, draw a segment 3 units in the negative direction. • To plot the z-coordinate, draw a segment 3 units in the negative direction. • Label the coordinate A. • Draw the rectangular prism and label each vertex.

shortest side of right prism 4.2 5 shortest side of left prism ¬ 0.5

¬8.5 longest side of right prism 21. 25 longest side of left prism ¬ 2.5

¬8.5 medium side of right prism 17 medium side of left prism ¬ 2.0

z

¬8.5 The ratios of the measures are equal, so the prisms are similar. Since the scale factor is not 1, the solids are not congruent.

(0, 3, 0)

O (0, 0, 0) y

(0, 3, 3) (3, 3, 0)

(0, 0, 3) (3, 0, 0)

A (3, 3, 3) x

Extra Practice

564

(3, 0, 3)

2. • Plot the x-coordinate first. Draw a segment from the origin 1 unit in the negative direction. • To plot the y-coordinate, draw a segment 2 units in the positive direction. • To plot the z-coordinate, draw a segment 3 units in the negative direction. • Label the coordinate E. • Draw the rectangular prism and label each vertex.

( 4, 0, 0) (0, 0, 0)

Q ( 4, 2, 4)

x (0, 2, 4)

( 1, 0, 0) (0, 0, 0)

y

(0, 2, 0)

E ( 1, 2, 3)

x (0, 0, 3)

(0, 0, 4)

6. • Plot the x-coordinate first. Draw a segment from the origin 3 units in the negative direction. • To plot the y-coordinate, draw a segment 1 unit in the positive direction. • To plot the z-coordinate, draw a segment 4 units in the negative direction. • Label the coordinate Y. • Draw the rectangular prism and label each vertex.

( 1, 2, 0) O

y ( 4, 0, 4)

O

(0, 2, 0)

z

( 1, 0, 3)

z

( 4, 2, 0)

(0, 2, 3)

3. • Plot the x-coordinate first. Draw a segment from the origin 3 units in the positive direction. • To plot the y-coordinate, draw a segment 1 unit in the negative direction. • To plot the z-coordinate, draw a segment 2 units in the positive direction. • Label the coordinate I. • Draw the rectangular prism and label each vertex.

z ( 3, 0, 0) ( 3, 1, 0) (0, 0, 0)

y O

(0, 1, 0)

Y ( 3, 1, 4)

z x (0, 0, 4)

(0, 0, 2) (0, 1, 2)

(0, 1, 4)

( 3, 0, 4)

(3, 0, 2)

7. Find the distance.

O (0, 0, 0) y

I (3, 1, 2)

AB ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

(0, 1, 0)

(3, 1, 0) x

¬ [3 ( 3)]2 (3 3)2 ( 1 1 )2

(3, 0, 0)

¬76 or 219 Find the midpoint.

4. • Plot the x-coordinate first. Draw a segment from the origin 2 units in the positive direction. • To plot the y-coordinate, draw a segment 1 unit in the negative direction. • To plot the z-coordinate, draw a segment 3 units in the positive direction. • Label the coordinate Z. • Draw the rectangular prism and label each vertex.

O

x

y y

z z

¬(0, 0, 0) 8. Find the distance. OP ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2 ¬ (2 2)2 [4 (1)]2 [ 4 (3)] 2 ¬42 Find the midpoint.

(2, 0, 3)

x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

(0, 0, 0) y

(2, 1, 0)

x x

3 11 3 3 ¬ , 3 2, 2 2

z (0, 0, 3)

(0, 1, 3)

Z (2, 1, 3) (0, 1, 0)

1 2 1 2 1 2 M ¬ 2 , 2 , 2

2 1 4 3 4 2 ¬ 2 , 2, 2

(2, 0, 0)

¬(0, 1.5, 3.5) 9. Find the distance. DE ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

5. • Plot the x-coordinate first. Draw a segment from the origin 4 units in the negative direction. • To plot the y-coordinate, draw a segment 2 units in the negative direction. • To plot the z-coordinate, draw a segment 4 units in the negative direction. • Label the coordinate Q. • Draw the rectangular prism and label each vertex.

2 ¬ (0 0 )2 [5 (5)] [3 (3)]2


x x

y y

z z

1 2 1 2 1 2 M ¬ 2, 2, 2

0 5 5 3 3 0 ¬ 2 , 2, 2

¬(0, 0, 0)

565

Extra Practice

10. Find the distance. JK ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

12. Find the distance. ST ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

¬ [3 ( 1)]2 (5 3)2 ( 3 5)2

2 ¬ [6 (8)] (1 3)2 [2 (5 )]2


x x

y y

z z


1 2 1 2 1 2 M ¬ 2 , 2 , 2

5 3 1 3 5 ¬ , 3 2 , 2 2 ¬(1, 1, 1) 11. Find the distance. AZ ¬ (x2 x1)2 (y2 y1)2 (z2 z1)2

¬(1, 1, 1.5)

¬153 or 317 Find the midpoint. x x

y y

z z

1 2 1 2 1 2 M ¬ 2 , 2 , 2

4 5 3 2 1 6 ¬ 2 , 2 , 2

¬(1, 2, 1.5)

Extra Practice

y y

z z

1 8 6 5 2 ¬ , 3 2 , 2 2

¬ (4 2)2 (5 1)2 (3 6)2

x x

1 2 1 2 1 2 M ¬ 2 , 2 , 2

566

Mixed Problem Solving and Proof Solve: AB ¬ (x2 x1)2 (y2 y1)2

Chapter 1 Points, Lines, Planes, and Angles

¬ (6 0)2 (2 6)2 ¬100 or 10 BC ¬ (x2 x1)2 (y2 y1)2

Page 782 1–3. Sample answer:

back

top

B

line 2

C

line 3

5. 6. 7.

¬ (8 0 )2 ( 4 6)2 ¬164 or 241 The perimeter is 10 102 241 or approximately 36.9 units. Examine: The perimeter is between 30 and 40 units, which makes sense for a triangle whose vertices have coordinates that are between 5 and 10 units apart. 9. Use the Midpoint Formula. For AB,

A

line 1 front

4.

¬ [8 ( 6)]2 [4 (2)] ¬200 or 102 AC ¬ (x2 x1)2 (y2 y1)2

Three planes suggested by the outline are the top, back, and front planes. Three lines that do not intersect are line 1, line 2, and line 3. See the figure for Exercises 1–3. Points A, B, and C might be coplanar, but they are not collinear. Each measurement is to the nearest foot. So the measurements are precise to within 0.5 feet. The measurement is precise to within 0.5 feet. So the height is between 621.5 feet and 622.5 feet. Explore: The Weston Centre could be as tall as 444.5 feet and as short as 443.5 feet. The Tower Life building could be as tall as 404.5 feet and as short as 403.5 feet Plan: Calculate the difference twice, using heights that give the greatest possible difference and then using heights that give the least possible difference. Solve: The greatest possible height difference is 444.5 403.5 or 41 feet. The least possible height difference is

6 8 2 (4)

6 8 4 ¬ , 22 2

¬(1, 3) For AC,

x x

y y

1 2 1 2 M ¬ 2 , 2

8 6 (4) 0 ¬ 2 , 2 8 4 0 6 ¬ 2 , 2

¬(4, 1) 10. Use the points (3, 2), (1, 3), and (4, 1) (which were found in Exercise 9), and follow the same steps as in Exercise 8. d1 ¬(x x1)2 (y2 y1)2 2 2 ¬ [1 (3)] (3 2)2 ¬41 d2 ¬(x x1)2 (y2 y1)2 2 2 [1 ¬ (4 1) ( 3)]2 ¬25 or 5 d3 ¬(x x1)2 (y2 y1)2 2

x

B (6, 2 )4

y y

¬2, 2

A(0, 6)

4

x x

1 2 1 2 M ¬ 2, 2

y

4

¬(3, 2) For BC,

4 8

y y

0 (6) 6 (2) ¬2, 2 6 62 0 ¬ 2 , 2

443.5 404.5 or 39 feet. So, the difference in heights is between 39 and 41 feet. Examine: The two given tower heights have a difference of 444 404 or 40 feet. This is in the range that was calculated. 8. Explore: The perimeter is the sum of the side lengths. 8

x x

1 2 1 2 M ¬ 2, 2

8

¬ [4 ( 3)]2 [1 2]2 ¬50 or 52 The perimeter is 5 52 41 or approximately 18.5 units. 11. ABC has a perimeter of 10 102 241 , which is twice the perimeter of the smaller triangle.

C ( 8 , 4 )

8

Plan: Use the Distance Formula to find the three side lengths. Then add them to find the perimeter.

567

Mixed Problem Solving and Proof

12. Explore: The exit numbers represent distances in miles. Plan: Find the exit number for the point halfway between Exits 128 and 184, then add 3.

3. Sixteen states are contained in the left circle, including the overlap region. 4. Twelve states are contained in the right circle, including the overlap region. 5. Seven states are in the overlap region, which represents states that have less than 2,000,000 people and are less than 34,000 square miles in area. 6. What the March Hare is talking about is the rule “If Alice means it, Alice says it.” What Alice is talking about is the rule “If Alice says it, Alice means it.” The Hatter is correct; Alice exchanged the hypothesis and conclusion. 7. “Say what you mean” translates as “If you mean it, say it,” and “Mean what you say” translates as “If you say it, mean it.” The two are converses of each other. 8. Let p and q represent the parts of the statement. p: An unknown person attempts to give one an item q: One does not accept it and notifies airline personnel immediately. Given: p → q and p Conclusion: She (Candace) should not accept it and she should notify airline personnel immediately 9. Given: B is the midpoint of A C and C is the midpoint of B D . Prove: A B C D

184 128 Solve: midpoint or 156 2

13.

14.

15.

16. 17.

156 3 159 The exit number for the Hays exit is 159. Examine: Exits 159 and 128 are 159 128 or 31 miles apart. Exits 184 and 159 are 184 159 or 25 miles apart. It makes sense that the answer is 159 since 159 is about halfway between 128 and 184 but is closer to 184. If there are forty gondolas, the spokes form 40 equal-sized angles that add up to 360°. Each 360 angle will have a measure of 40 or 9. Because A, B, and D lie along a straight line, ABC and CBD form a linear pair and are supplementary. Because the two angles are supplementary, mABC mCBD ¬180 110 mCBD ¬180 mCBD ¬70 Sample answer: isosceles triangle, rectangle, pentagon, hexagon, square triangle: convex irregular; rectangle: convex irregular; pentagon: convex irregular; hexagon: concave irregular; square: convex regular

A

C

D

Proof: By the definition of midpoint, AB BC and BC CD. By the Transitive Property of Equality, AB CD. By definition of congruence, B A C D .

Chapter 2 Reasoning and Proof Page 783 1. The statement is true for every state in the table except Michigan. The population density for Michigan increased by 162.6 137.7 or 24.9 during the first period and by 175.0 162.6 or 12.4 during the second period: less than 30 both times. 2. Sample answer: Explore: There is enough information to make a projection about the 2010 population density of any of the five states listed. Plan: Estimate the 2010 population density for California and Michigan. First, estimate the increase per decade. Then add this number to the given 2000 figure to get an estimated 2010 figure. Solve: For California, the population density increased by 217.2 100.4 or 116.8 over four

10. Given: k (T t) Prove: T k t

Proof: Statements

1. k (T t) 2. k(T t)

3. T t k 4. T k t

Reasons 1. Given 2. Multiplication 3. Division 4. Addition

11. Given: ABCD has 4 A congruent sides. DH BF AE; EH FE Prove: AB BE AE AD AH DH

116.8 decades, an increase of 4 29.2 or about 30 per decade. The population in 2000 is about 215, so in 2010 it should be about 215 30 or 245 people per square mile. For Michigan, the population density increased by 175.0 137.7 or 37.3 over four decades, an

Proof: Statements

37 .3 increase of 4 9.325 or about 10 per decade. The population in 2000 is 175, so in 2010 it should be about 175 10 or 185 people per square mile.


B

B F G

E H

D

C Reasons

1. DH BF AE; EH FE 1. Given 2. Segment 2. BE BF FE and Addition AE EH AH Property

568

3. BF FE AH 4. BF FE AE EH 5. BE AH 6. ABCD has 4 congruent sides. 7. AB AD

8. AB BE AD AH 9. AB BE AE AD AH DH

4. 1 and 5 are alternate interior angles. 5 ¬1 m5 ¬m1 m5 ¬75 5. 2 and 6 are alternate interior angles. 6 ¬2 m6 ¬m2 m6 ¬75 6. 1 and 7 are vertical angles. 7 ¬1 m7 ¬m1 m7 ¬75 7. Use the information about 5 and 6 found in Exercises 4 and 5. m5 m6 m8 ¬180 75 75 m8 ¬180 150 m8 ¬180 m8 ¬30 8. 8 and 9 are vertical angles, and m8 30 (Exercise 7). 9 ¬8 m9 ¬m8 m9 ¬30 9. 6 and 10 are corresponding angles, and m6 75 (Exercise 5). 10 ¬6 m10 m6 m10 ¬75 10. 10 and 11 are alternate interior angles, and m10 75 (Exercise 9). 11 ¬10 m11 ¬m10 m11 ¬75 11. Given: M Q N P 4 3 Prove: 1 5

3. Substitution 4. Addition 5. Transitive Property 6. Given 7. Definition of congruent segments 8. Addition 9. Addition

12. The vertical lines are parallel. The first pair of vertical lines appear to curve inward, the second pair appear to curve outward. 13. Given: 4 2 Prove: 3 1 4 3 2 1

Proof: Statements

Reasons

1. 4 2 2. 4 and 3 form a linear pair; 2 and 1 form a linear pair. 3. 4 and 3 are supplementary; 2 and 1 are supplementary. 4. 3 1

1. Given 2. Definition of linear pair 3. Supplement Theorem 4. Angles supplementary to congruent angles are congruent.

M

N 1

O

2 3 4 5 6

P

Q Proof:

Chapter 3 Parallel and Perpendicular Lines Page 784

Statements

Reasons

1. MQ N P ; 4 3 2. 3 5

1. Given 2. Alternate interior angles are congruent. 3. Transitive Property

3. 4 5

1. Alternate interior angles are congruent, so 1 2. 2. 1 and 3 form a linear pair. m1 m3 ¬180 75 m3 ¬180 m3 ¬105 3. 2 and 4 form a linear pair. m2 m4 ¬180 75 m4 ¬180 m4 ¬105

4. 1 4 5. 1 5

569

4. Corresponding angles are congruent. 5. Transitive Property


12. Explore: The information includes an increaseper-year rate and a cost for the year 2000. Plan: Write a linear equation for the cost, with t 0 in the year 2000. Then find the cost for t 10. Solve: C mt b The slope m is 84.2, and b equals 2600, which is the cost in the year 2000, when t 0. C 84.2t 2600 In 2010, t 10. C 84.2(10) 2600 C 3442 The total average cost in 2010 will be $3442. Examine: Check by working the problem in reverse: the increase between 2000 and 2010 is 3442 2600 or $842. 84 2 The rate of increase is 10 or $84.20 per year.

Chapter 4 Congruent Triangles Page 785 1. The triangles appear to be scalene. One leg of each right triangle looks longer than the other leg.

2. The triangles appear to be isosceles. Two of the sides appear to be the same length.

13. Let y mx b, where y represents the amount of water and x represents the number of hours the pool has been draining. At the start of the draining process, t 0 and the pool holds 74,800. The rate, m, equals 1200. So, y 1200x 74,800, or y 74,800 1200x. 14. Use the equation found in Exercise 13. Set y equal to 0 and then solve for x. y ¬74,800 1200x 0 ¬74,800 1200x 74,800 ¬1200x

3. Use the Exterior Angle Theorem. The angle with measure 93 is an exterior angle of LEO. So the measure of this angle equals the sum of the measures of the two remote interior angles, O and OLE. mO mOLE ¬93 27 mOLE ¬93 mOLE ¬66 4. The A-frame is symmetric, so that triangles on the left are congruent to corresponding triangles on the right: BED CFG; BJH CKM; BPN CQS; DIH GLM; DON GRS. 5. Yes; because E bisects the line segments that pass through it, G E C E and B E H E . Also, GEH and CEB are vertical angles and are therefore congruent. So GHE CBE by SAS. 6. Yes; G E G E by the Reflexive Property. Because E bisects the line segments that pass through it, E A IE . Because the overall shape is a square, G A IG . So AEG IEG by SSS. , A Since E bisects AI E IE . GA GI, so GIE GAE. Therefore, AEG IEG by SAS. CI IG AG ; AI GC 7. Given: AC Prove: ACI CAG A B C

18 7 3 ¬x 18 7 1 It will take 3 or 62 3 hours to drain the pool.

15. If two lines in a plane are cut by a transversal so that corresponding angles are congruent, then the lines are parallel. 16. Given: 1 3, A B D C Prove: B C A D A B 2

1 4

3

D

C

Proof: Statements

Reasons

1. A B DC 2. 4 1

1. Given 2. Alternate interior angles are congruent. 3. Given 4. Transitive Property

3. 1 3 4. 4 3 C A D 5. B

E D

5. If corresponding angles are congruent, then the lines are parallel.

F

G Proof:

17. The shortest distance is a perpendicular segment from the bus station to Denny Way. However, you cannot walk this route because there are no streets that exactly follow this route and you cannot walk through or over buildings.

CI

H

AG

Given

AI

GC

CA

Reflexive Prop.

570

ACI SSS

Given

CA


I

CAG

8. Yes, the method is valid. Thales sighted SPQ and SQP. He then constructed QPA congruent to SPQ and PQA congruent to SQP. S

P

Chapter 5 Relationships in Triangles Page 786 1. Use the compass and straightedge to construct the perpendicular bisector of each side. The point where all three bisectors intersect is the circumcenter.

Q

C

2. Use the compass and straightedge to construct the perpendicular bisector of each side and thereby locate the midpoint of each side. Then draw the three medians of the triangle. The point where all three medians intersect is the centroid.

A SPQ and APQ share the side P Q . Since QPA SPQ, PQA SQP, and Q P P Q , SPQ APQ by the ASA Postulate. 9. Given: P H bisects Y YHX, H P Y X Prove: YHX is an H P isosceles triangle. Proof:

D

3. For each vertex, use the compass and straightedge to construct a line that passes through the vertex and is perpendicular to the opposite side. The point where these three lines intersect is the orthocenter.

X

Statements

Reasons

1. PH bisects YHX. 2. YHP XHP

1. Given 2. Definition of angle bisector 3. Given 4. Definition of perpendicular lines 5. All right angles are congruent. 6. Third Angle Theorem 7. Converse of the Isosceles Triangle Theorem 8. Definition of isosceles triangle

3. PH Y X 4. YPH and XPH are right angles. 5. YPH XPH 6. Y X 7. H X H Y

8. YHX is an isosceles triangle.

10. Given: ABC is a right isosceles triangle. M is the midpoint of A B . Prove: C M A B

O 4. For each of the triangle’s three angles, use the compass and straightedge to construct the angle bisector. The point where all three angle bisectors intersect is the incenter.

K 5. Explore: The angle measures are unknown, but information is given about relationships among the three measures. Plan: Write and solve a system of equations with the three angle measures as variables. Solve: Let x mA, y mB, and z mC. Solve the following system, which represents the information given in the problem and also uses the Angle Sum Theorem: xy2 z 2y 14 x y z 180 Use the first two equations to make substitutions in the third equation. (y 2) y (2y 14) ¬180 4y 12 ¬180 4y ¬192 y ¬48 Find x and z. xy2 48 2 or 50

y

B (0, a) M C (0, 0) A (a, 0) x

Proof: Place the triangle so that the vertices are A(a, 0), B(0, a), and C(0, 0). By the Midpoint Formula, the coordinates of M are 0 a a0 a a 2 , 2 or 2, 2.

B and C M . Find the slopes of A a 0 a Slope of A B 1 a0 a a

0

2

0

2 Slope of C M a

a 2 a 2

1

The product of the slopes is 1, so C M A B .

571


z 2y 14 2(48) 14 or 82 So mA 50, mB 48, and mC 82. Examine: The three angle measures should add up to 180: 48 50 82 180. 6. The shortest side is opposite the smallest angle, and the longest side is opposite the largest angle. Since, from Exercise 5, mB mA mC, it follows that AC BC BA. The order of lengths from least to greatest is AC, BC, BA. 7. Explore: The lengths of the legs are unknown, but information is given about relationships among the three lengths. Plan: Write and solve a system of equations with the three lengths as variables. Solve: Let the shortest, middle, and longest leg be represented by x, y, and z, respectively. Solve the following system, which represents the information given in the problem: x y z 68

Step 2: x y 634 Step 3: This contradicts the fact that x y 634. Therefore, at least one of the legs was longer than 317 miles. 10. Let n distance from Bozeman to Boise. Solve each inequality to determine the range of values for n. 341 294 n 341 n 294 n 294 341 635 n n 47 n 47 Graph the inequalities on the same number line. n 635 635

n 47 47

n 47 47

y 1 2 x 11 3 z 4x 12

Use the last two equations to make substitutions in the first equation. 3 x 1 2 x 11 4 x 12 4x (2x 44) (3x 48) 9x 92 9x x Find y and z.

¬68

Proof:

¬272 ¬272 ¬180 ¬20

Statements 1. 2. 3. 4.

y 1 2 x 11 1 2(20) 11 or 21

ZST ZTS Z S T Z SZ TZ TA AZ TZ

5. TA 2AX 6. 2AX AZ TZ 7. XRA XAR 8. X R X A 9. XR XA 10. 2XR AZ TZ 11. 2XR AZ SZ

z 3 4 x 12 3 4(20) 12 or 27

So, the three leg lengths are 20 miles, 21 miles, and 27 miles. Examine: The three lengths should add up to 68: 20 21 27 68. 8. If the crime was committed on a Tuesday between 3 P.M. and 11 P.M., this could be used to prove that the man is innocent. For an indirect proof, start by assuming that the conclusion is not true. Since we want to prove that the man is innocent, assume that he is guilty. We assume that the conditional, “If it is Tuesday between 3:00 P.M. and 11:00 P.M., the man is at work” is true. If the crime took place on a Tuesday between 3:00 P.M. and 11:00 P.M. and the man is guilty, he could not have been at work. So for the conditional statement, the hypothesis is true while the conclusion is false. This makes the conditional statement false. This contradiction means that the assumption that the man is guilty is false. So the man is innocent. 9. Given: x y 634 Prove: x 317 or y 317 Proof: Step 1: Assume x 317 and y 317.


635

47

The range of values that fit all three inequalities is 47 n 635. 11. Given: ZST ZTS S T XRA XAR R TA 2AX X Prove: 2XR AZ SZ Z

A

Reasons 1. 2. 3. 4.

Given Isos. Triangle Theorem Def. of congruent Triangle Inequality Theorem 5. Given 6. Substitution 7. Given 8. Isos. Triangle Theorem 9. Def. of congruent 10. Substitution 11. Substitution

12. The 95° angle measure is greater than the 80° angle measure. By the SAS Inequality/Hinge Theorem, the distance from Warm Springs to Beatty is greater. 13. Given: DB is a median D A C of ABC. 1 2 m1 m2 Prove: mC mA B Proof:

572

Statements

Reasons

1. DB is a median of ABC. m1 m2 2. D is the midpoint of A C . 3. A D D C

1. Given

2. Definition of median 3. Midpoint Theorem

4. DB D B 5. AB BC 6. mC mA

6. Given: WX Q R , Z X S R Prove: W ZQ S

3. Midpoint Theorem 4. Reflexive Property 5. SAS Inequality 6. If one side of a triangle is longer than another, the angle opposite the longer side is greater than the angle opposite the shorter side.

W

R X Y Proof: We are given that W X Q R , Z X S R . By the Corresponding Angles Postulate, XWY RQY and YXZ YRS. By the Reflexive Property, QYS QYS, QYR QYR and RYS RYS. QYR WYX and YRS YXZ by AA Similarity. By the definition of YX YX ZY W Y similar triangles, QY YR and YR S Y . W Y Z Y by the Transitive Property. WYZ QY SY

1. Explore: The problem gives information about how much was spent on toys for children, on the size of the U.S. population, and what percent of the U.S. population is children. Plan: Multiply the U.S. population by the percent that are children, then divide the answer into the total money spent to find the money spent per child. Estimate: 21.4% is about 25% or 1 4. 1(280,000,000) 70 million 4

QYS by SAS Similarity. By the definition of similar triangles YWZ YQS. W Z Q S by the Corresponding Angles Postulate. 7. The bar connects the midpoints of each leg of the letter and is parallel to the base. Therefore, the length of the bar is one-half the length of the base because a midsegment of a triangle is parallel to one side of the triangle, and its length is one-half the length of that side. 1 8. The thickness of the major stroke is 1 2 of the

35 billion 500 70 million

Solve: Find the number of children under 14. 0.214(281,421,906) 60,224,288 Now find the amount spent per child.

1 (3) or 0.25 cm. letter height, namely 12

9. Given: WS bisects RWT, 1 2

34,554,900,000 573.77 60,224,288

The average amount spent per child was approximately $573.77. Examine: Between $500 and $600 per child is close to the estimate, so the answer is reasonable.

V

W

2 1

VW R S Prove: WT ST

R

S

T

Proof:

2. The largest number that divides evenly into both 77 and 110 is 11. So the greatest side length that will work for the quilt squares is 11 inches. 3. The quilt will measure 77 inches by 110 inches, or 7 eleven-inch squares by 10 eleven-inch squares. The quilt will require 7 10 or 70 squares. side length of a quilt square 11 4. 3

Statements

4

44 3

Reasons

1. 2. 3. 4.

S W bisects RWT RW R S WT ST 1 2 W R V W

5. 6.

RW VW VW R S WT ST

1. 2. 3. 4.

Given Angle Bisector Theorem Given Converse of Isosceles Triangle Theorem 5. Definition of congruent 6. Substitution Property

10. Since BDF BCI and the ratio of side lengths is 2 : 1, the ratio of perimeters will be 2 : 1 by the Proportional Perimeters Theorem. 11. Sample answer: BCI BZJ and both are isosceles right triangles with a ratio of side lengths of 2 : 3. By the Proportional Perimeters Theorem, the ratio of their perimeters will be 2 : 3.

5. Given: WYX QYR, ZYX SYR Prove: WYZ QYS U V Q T W P

S Z

Page 787

4 4 The scale factor is 3 .

V

Q

P

Chapter 6 Proportions and Similarity

side length of the pattern

U T

S Z

R X Y Proof: It is given that WYX QYR and ZYX SYR. By definition of similar polygons YX YX W Y ZY we know that QY YR and YR SY . Then W Y Z Y by the Transitive Property. WYZ QY SY QYS because congruence of angles is reflexive. Therefore, WYZ QYS by SAS Similarity.

573


12. First find the perimeter of WVU. UV VW UW 500 400 300 1200 Now use the Proportional Perimeters Theorem. ST U V 100 0 500

2

2. The distance from the roller coaster to the bumper boats is the geometric mean of the distances labeled 150 ft and 50 ft. 50 x x ¬ 150

perimeter of RST ¬ perimeter of WVU x ¬ 12 00 x ¬ 1200

x2 ¬50 150 x2 ¬7500 x ¬86.6 The distance from the roller coaster to the bumper boats is about 86.6 feet.

2400 ¬x The perimeter of RST is 2400 feet.

3. No, the diagram is not correct. The measures do not satisfy the Pythagorean Theorem, since (2.7)2 (3.0)2 (5.3)2 or 16.29 28.09 4. At the middle of the pinwheel, the blue angles measure 60° and the red angles measure 45°. Let x represent the measure of one of the numbered angles. 3x 3(60) 3(45) ¬360 3x 315 ¬360 3x ¬45 x ¬15 Each of the numbered angles measures 15°. 5. PR RO PO because PRO is equilateral

13. First, write an equation to find the balance after 6 months. The interest rate is half of 2.5%, or 1.25%. Then use a calculator to repeat the process a total of 10 times (5 years). current balance (current balance interest rate) new balance 5000 (5000 0.0125) 5062.5 5062.5 (5062.5 0.0125) 5125.78 5125.78 (5125.78 0.0125) 5189.85 5189.85 (5189.85 0.0125) 5254.73 5254.73 (5254.73 0.0125) 5320.41 5320.41 (5320.41 0.0125) 5386.92 5386.92 (5386.92 0.0125) 5454.25 5454.25 (5454.25 0.0125) 5522.43 5522.43 (5522.43 0.0125) 5591.46 5591.46 (5591.46 0.0125) 5661.35 The amount in the account after 5 years will be $5661.35.

R Q P

blue triangle 60

T 30

red triangle

Chapter 7 Right Triangles and Trigonometry

O S

First find the length of PO. In 30°-60°-90° triangle PQO, P Q is the shorter leg and Q O is the longer leg. Let x PQ. x 3 ¬QO x 3 ¬4 x ¬4

Page 788 1. Given: D is the midpoint of B E , B D is an altitude of right triangle ABC. AD D E Prove: D E DC

B C A

3

Reasons

SO PR 8 3

SO ¬2 (ST) 8 ¬2 (ST)

3 8 ¬ST ( 3)(2 ) ST ¬8 6

One red triangle and one blue triangle together form a “petal”, whose perimeter (adding lengths clockwise) is 32 8 8 8 8 8 8 or 3

6

along red triangle

3

6

3

3

3

along blue triangle

3

5. Substitution


3

So the side of the equilateral triangle is 8. 3 STO is an isosceles right triangle with hypotenuse

1. BD is an altitude 1. Given of right triangle ABC. AD D B 2. The measure of an altitude 2. D B DC drawn from the vertex of the right angle of a right triangle to its hypotenuse is the geometric mean between the measures of the two segments of the hypotenuse. 3. D is the midpoint 3. Given of B E . 4. Definition of midpoint 4. DB DE AD D E 5. D E DC

3

PR 2(PQ) 2 4 or 8

E

Proof: Statements

D

or about 55 inches. The total perimeter is 3 32

574

h tan47° ¬ 65 00 6500tan47° ¬h 6970 ¬h The cloud ceiling is about 6970 feet high. 11. Use the Law of Sines. Let x be the measure of the angle opposite the shortest side.

6. Since the guy wires are equally spaced apart, XG 60. The isosceles triangles are AEX, AHX, DFX, DGX, AEH, CFG, BEH, and DFG. 7. AX 4(60) 240. Because AEX is an isosceles right triangle, EX 240. BX 3(60) 180, so if x mBEX, B X tan x EX 18 0 tan x 240

sin x sin 1 03° 7.5 ¬ 14 7.5sin 103° sin x ¬ 14 7.5sin 103° x ¬sin1 14

tan x 3 4 x tan13 4

¬31.465 The third angle measure is about 180 103 31.465 or 45.535. So the two unknown angle measures are approximately 31 and 46.

36.9 CX 2(60) 120, so if y mCFX, C X tan y ¬ FX 12 0 tan y ¬ 60

12. Use the angle measure 45.535, found in Exercise 11, to find the length of the opposite side.

tan y ¬2 y ¬tan12 ¬63.4 So mBEX 36.9 and mCFX 63.4. 8. Find AE using AX 4(60) 240.

sin 1 03° sin45 .535° ¬ x 14

xsin103° ¬14sin45.535° 14sin 4 5.535° x ¬ sin 103° ¬10.254 The sum of all three sides is about 7.5 14 10.254 or about 31.8 feet. 13. Use the Pythagorean Theorem to find GE. GE2 GH 2 EH 2 GE2 2502 1502 GE2 85,000 GE 291.55 Since GF GE, GF 291.55. Use the Law of Cosines to find EF. EF2 GE2 GF 2 2(GE)(GF)cos40° EF2 85,000 85,000 2(85,000)cos40° EF2 39,772.44 EF 199.43 The total amount of fencing is GH GF EF 250 291.55 199.43 741 So the amount of fencing needed is about 741 feet.

AX cos45° ¬ AE 24 0 cos45° ¬ AE 24 0 AE ¬ cos 45° ¬339.4 AE 339.4 feet. Find EB using the Pythagorean Theorem with EX AX 240 and BX 3(60) 180. EX2 BX2 ¬EB2 2402 1802 ¬EB2 90,000 ¬EB2 300 ¬EB EB 300 feet. Find CF using the Pythagorean Theorem with CX 2(60) 120 and FX 60. CX2 FX2 ¬CF 2 1202 602 ¬CF 2 18,000 ¬CF 2 134.2 ¬CF CF 134.2 feet.

Chapter 8 Quadrilaterals

Find DF. Since DFX is an isosceles right triangle with legs with length of 60, DF 602 or about 84.9 feet.

Page 789 1. Use the Interior Angle Sum Theorem. S 180(n 2) 180(32 2) 5400 The sum of the measures of the interior angles of The London Eye is 5400. 2. From Exercise 1, the sum of the measures of the 32 congruent interior angles is 5400, so the measure of one interior angle of The London Eye 54 00 is 32 or 168.75. 3. Sample answer: Make sure that opposite sides are congruent or make sure that opposite angles are congruent.

9. First, add the lengths of all the wires on the left side, using the results from Exercise 8. AE EB CF DF 339.4 300 134.2 84.9 858.5 Now double this result to get the total amount of wire used: 2(858.5) or 1717 feet. 10. clouds

h 47

light

6500

station

Use trigonometry to find h.

575


4. Given: ABCD, A E C F Prove: Quadrilateral EBFD is a parallelogram.

11. mXWY 90 mXZY 90 12. X, Y, XWY, and XZY are rt. 13. WXZY is a rect.

A E

B

D

F C

Reasons

ABCD, A E C F B A D C A C BAE DCF B E D F , BEA DFC 6. B C A D 7. DFC FDE 8. BEA FDE 1. 2. 3. 4. 5.

9. E B D F 10. Quadrilateral EBFD is a parallelogram.

1. 2. 3. 4. 5.

P

Given Opp. sides of a are . Opp. of a are . SAS CPCTC

R N

Def. of Alt. Int. Angles Th. Transitive Property Corresponding Angles Postulate 10. If one pair of opp. sides is and , then the quad. is a .

1 2

Z

Proof:

1. WXZY, 1 and 2 are complementary 2. m1 m2 90 3. m1 m2 mX 180 4. 90 mX 180 5. mX 90 6. X Y

Reasons 1. Given 2. Def. of complementary 3. Angle Sum Theorem 4. Substitution 5. Subtraction 6. Opp. of a are . 7. Substitution 8. Cons. in are suppl.

7. mY 90 8. X and XWY are suppl. X and XZY are suppl. 9. mX mXWY 180 9. Def. of suppl. mX mXZY 180 10. 90 mXWY 180 10. Substitution 90 mXZY 180


M

Proof: The diagram indicates that KNS SNM MLQ QLK and NKS SKL LMQ QMN in KLMN. Since KLR, KNS, MLQ, and MNP all have two angles congruent, the third angles are congruent by the Third Angle Theorem. So QRS KSN MQL SPQ. Since they are vertical angles, KSN PSR and MQL PQR. Therefore, QRS PSR PQR SPQ. PQRS is a parallelogram since if both pairs of opposite angles are congruent, the quadrilateral is a parallelogram. KSN and KSP form a linear pair and are therefore supplementary angles. KSP and PSR form a linear pair and are supplementary angles. Therefore, KSN and PSR are supplementary. Since they are also congruent, each is a right angle. If a parallelogram has one right angle, it has four right angles. Therefore, PQRS is a rectangle. 8. Sample answer: He should measure the angles at the vertices to see if they are 90 or he can check to see if the diagonals are congruent. 9. The legs of the trapezoids are part of the diagonals of the square. The diagonals of a square bisect opposite angles, so each base angle of a trapezoid measures 45°. One pair of sides is parallel and the base angles are congruent. 10. Since the perimeter of the floor tile is 48 inches, 4 8 the measure of each side is 4 or 12 inches. Similarly, the measure of each side of the red square is 4 inches. So, the sum of the measures of the bases of a trapezoid is 12 4 or 16 inches. The trapezoids are isosceles, so the lengths of the two remaining sides are the same. We need the height of a trapezoid to find the lengths of the remaining sides. Since the heights of the trapezoids are identical, the sum of twice the height of the trapezoid and the width of the red square is equal to width of the floor tile or 12 inches. Find the height of a trapezoid. 2h 4 ¬12 2h ¬8 h ¬4 The height of a trapezoid is 4 inches. Notice that the height and side of a trapezoid and one third of 12 the side of the floor tile 3 or 4 inches form a

6. 7. 8. 9.

Statements

13. Def. of rectangle

Q

S

5. The legs are made so that they will bisect each other, so the quadrilateral formed by the ends of the legs is always a parallelogram. Therefore, the top of the stand is parallel to the floor. 6. Given: WXZY, 1 and 2 are complementary. Prove: WXZY is a rectangle. W Y

X

12. Def. of rt.

7. Given: KLMN Prove: PQRS is a rectangle. K L

Proof: Statements

11. Subtraction

576

45°-45°-90° right triangle. So, the length of the side of a trapezoid is 2 times the height or 42 inches, and the sum of two sides is 82 inches. Therefore, the perimeter of one trapezoid is 16 82 or about 27.3 inches. 11. Given: Quadrilateral QRST Prove: QRST is an isosceles trapezoid ¬ y T( b, c) S(b, c)

Q( a, 0) O

R(a, 0)

4. The figure inside the square formed by the eight congruent yellow and blue triangles has rotational symmetry of order 8. Therefore, the 36 0° magnitude of the symmetry is 8 or 45°. Since the triangles alternate in color, either a single 45° clockwise or 45° counterclockwise rotation takes a yellow triangle to a blue triangle. 5. The figure inside the square formed by the eight congruent yellow and blue triangles has rotational symmetry of order 8. Therefore, the 36 0° magnitude of the symmetry is 8 or 45°. Since the triangles alternate in color, either a single 45° clockwise or 45° counterclockwise rotation takes a blue triangle to a yellow triangle. 6. There are four congruent trapezoids in the mosaic tile. These trapezoids share the same rotational symmetry of the entire square tile. The order of the rotational symmetry is 4, therefore, the magnitude 36 0° of the symmetry is 4 or 90°. So, either a single 90° clockwise or counterclockwise rotation takes a trapezoid to a consecutive trapezoid. 7. Yes; the mesure of one interior angle is 90, which is a factor of 360. So, a square can tessellate the plane. 8. Let the first and second whole number percent enlargements be represented in decimal form by a and b, respectively. Then ab 2 4 and ab 3 6. These two equations give the same 2 . There is more than one result: ab 2 or b a solution to this equation. For the case where a is 2 1.5, or 150%, b is 1.33, or 133%. 1.5 9. The initial path of the aircraft is due south, so a vector representing the path lies on the negative y-axis 190 units long. The wind is blowing due west, so a vector representing the wind will be parallel to the negative x-axis 30 units long.

x

Proof: TQ [b (a)]2 (c 0)2 2 2 2 b 2 ab a c 2 (c SR (b a) 0)2 2 2 b 2ab a c2

c c 0 Slope of T S b (b) 2b or 0. 0 0 0 R Slope of Q a (a) 2a or 0.

c 0 c Q Slope of T b (a) or b a. c0 c Slope of S R b a or b a.

Exactly one pair of opposite sides are parallel. The legs are congruent. QRST is an isosceles trapezoid.

Chapter 9 Transformations Page 790 1. The entire quilt square has 4 lines of symmetry. There is a horizontal line of symmetry through the center and a vertical line of symmetry through the center. There are also two diagonal lines of symmetry. 2. Sample answer: Look at the upper right-hand square containing two squares and four triangles. The blue triangles are reflections over a line representing the diagonal of the square. The purple pentagon is formed by reflecting a trapezoid over a line through the center of the square surrounding the pentagon. Any small pink square is a reflection of a small yellow square reflected over a diagonal of the larger square. 3. 30 m

N W

50

50

E

50 100 150 200

S

10. See Exercise 9 for a diagram of the vectors. The resultant path can be represented by a vector from the initial point of the vector representing the aircraft to the terminal point of the vector representing the wind. Use the Pythagorean Theorem. c2 a2 b2 c2 1902 302 c2 37,000 c 37,00 0 c 192.4

shortest distance 40 m

North and east are perpendicular directions, so let them correspond to two legs of a right triangle. The shortest distance between the starting point and the ending point is the hypotenuse of the right triangle formed. Use the Pythagorean Theorem. d2 302 402 900 1600 2500 d 50 The distance of the shortest path is 50 miles.

577


The resultant speed of the plane is about 192.4 miles per hour. Use the tangent ratio to find the direction of the plane.

The vertex matrix for the figure in Quadrant III is 4 5 7 5 4 3 1 3 . 6 4 4 1 2 1 4 4

y

3 0 tan ¬ 190 3 0 ¬tan1 190

O

x

¬9.0° The resultant direction of the plane is about 9.0° west of due south. Therefore, the resultant velocity and direction of the plane is about 192.4 miles per hour at about 9.0° west of due south. 11. Sample answer: The matrix

10 1 will produce 0

the vertices for a reflection of the figure in the 1 0 y-axis. Then the matrix will produce the 0 1 vertices for a reflection of the second figure in the x-axis. This figure will be upside down.

10

Chapter 10 Circles

Page 791 1. Since the tire travels about 50.21 inches during one rotation of the wheel, the circumference of the tire is 50.21 inches. The circumference of a circle is related to its diameter by C d, so the 50.27 diameter is d C

or about 16 inches. 2. The total number of students surveyed is equal to the sum of the numbers in the column on the right. 910 234 624 364 468 2600 The number of students that participated in the survey was 2600. The sum of the measures of the central angles of the sectors of a circle graph is 360. So, the number of degrees that would be allotted to each category is given by x n or x 9n, 360 2600 65 where x is the number of degrees and n is the number of students that chose a particular reason.

0 will produce the vertices for 1 a 180° rotation about the origin. The figure will be upside down and in Quadrant III. 13. The matrix for Exercise 12 has the first row entries for the first matrix used in Exercise 11 and the second row entries for the second matrix used in 11. 14. The vertex matrix for the figure in Quadrant I is 4 5 7 5 4 3 1 3 . 6 4 4 1 2 1 4 4 12. The matrix

The vertex matrix for the figure in Quadrant III can be obtained by either of the two methods outlined in the solutions to Exercises 11 and 12. First, use the consecutive reflections to obtain the vertex matrix. 1 0 4 5 7 5 4 3 1 3 0 1 6 4 4 1 2 1 4 4

0 1

4 5 7 5 4 3 1 3 6 4 4 1 2 1 4 4

0 4 5 7 5 4 3 1 3 6 4 4 1 2 1 4 4 1

4 5 7 5 4 3 1 3 4 4 1 2 1 4 4

6

Or use the rotation matrix to obtain the vertex matrix. 1 0 4 5 7 5 4 3 1 3 0 1 6 4 4 1 2 1 4 4

4 5 7 5 4 3 1 3 4 4 1 2 1 4 4

6

Number of Students

Number of Degrees Allotted

Learn about life beyond Earth

910

126°

Learn more about Earth

234

32.4°

Seek potential for human inhabitance

624

86.4°

Use as a base for further exploration

364

50.4°

Increase human knowledge

468

64.8°

Reason to Visit Mars

3. Each arc degree measure equals the measure of the central angle and is less than 180, so all of the categories are represented by minor arcs.


578

GR is tangent 7. Given: to D at G. G A D G Prove: A G bisects R D .

4. Learn more about life Increase beyond Earth human 35% knowledge 18% Seek potential Use as a base for human for further inhabitance exploration 24% 14%

Learn more about Earth 9%

R G

A

D Proof: Since D A is a radius, D G D A . Since G A D G D A , GDA is equilateral. Therefore, each angle has a measure of 60. Since G R is tangent to D, mRGD 90. Since mAGD 60, then by the Angle Addition Postulate, mRGA 30. If mDAG 60, then mRAG 120. Then mR 30. Then, RAG is isosceles, and R A A G . By the Transitive Property, R A A D . Therefore, A G bisects R D .

5. In a circle, if a diameter (or radius) is perpendicular to a chord, then it bisects the chord and its arc. With this fact and the given information, we can draw the figure below.

4 cm 4 cm

8. If a secant and a tangent intersect in the exterior of a circle, then the measure of the angle formed is one-half the positive difference of the measures of the intercepted arcs. B C is a tangent and A D is a secant that intersect in the exterior of the circle . (the rainbow). Find mAC mAC ) mB ¬1(mCD

x 3 cm

The height of the paperweight is equal to 4 x, and x is one leg of a right triangle with a hypotenuse with length 4 cm (the radius) and the other leg with length 3 cm (which is half of the diameter of the flat surface). Use the Pythagorean Theorem to find x. 42 ¬x2 32 16 ¬x2 9 7 ¬x2 7 ¬x 2.6 ¬x Therefore, the height of the paperweight is about 4 2.6 or 6.6 cm. 6. Given: MHT is a semicircle R H T M TR TH R T Prove: RH HM M

2

42 ¬1 2 (160 mAC) 42 ¬80 1 2 mAC ¬38 1mAC 2

¬76 mAC

9. Draw a model using a circle. Let x represent the measure of the unknown segment of the diameter. Use the products of the lengths of the intersecting chords to find the length of the diameter. 30 cm 50 cm

50 cm

x H Proof: Statements 1. MHT is a semicircle, RH T M 2. THM is a rt. .

3. 4. 5. 6. 7.

TRH is a rt. . THM TRH T T TRH THM TR TH RH HM

First, find x. 30 x ¬50 50 2 50 x ¬ 30 x ¬83.3 The diameter of the circle is about 30 83.3 or 113.3 cm, so the radius of the circle that contains 113.3 the arch is about 2 or 56.7 cm. 10. The diameter of Earth is 7,926 miles, so the radius 7,9 26 of Earth is 2 or 3,963 miles. Since 80% of the space junk orbits Earth at a distance of 1,200 miles, the radius of the orbit is 1,200 3,963 or 5,163 miles. The equation of a circle with center (0, 0) and radius of r units is given by x2 y2 r2. So, assuming that the orbit is circular, an equation that models the orbit of 80% of space junk with Earth’s center at the origin is x2 y2 26,656,569.

Reasons 1. Given

2. If an inscribed intercepts a semicircle, the is a rt. . 3. Def. of lines 4. All rt. are . 5. Reflexive Property 6. AA Similarity 7. Def. of s

579


Find the area of one of the larger trapezoids. b4

Chapter 11 Polygons and Area Page 792 1. The upper portion of the living area is a rectangle 36 feet long and 30 12 or 18 feet wide. The bedroom measures 16 ft by 12 ft. Living area Upper rectangle Bedroom A w A ¬w 36 18 ¬16 12 648 ¬192 The total living area is 648 192 or 840 ft2. 2. One-third of 840 (from Exercise 1) is 280 ft2. 3. The width of the sunroom is 36 16 8 12 ft. A ¬w 280 ¬ 12 ¬23.3 The dimensions of the new sunroom will be 12 ft by 23.3 ft. 4. Use the Pythagorean Theorem to find the height of the trapezoids.

16

12

10

6.

7.

b1

h

8.

12 20

h2 122 ¬202 h2 144 ¬400 h2 ¬256 h ¬16 The height of the trapezoids is 16 feet. 5. Only the trapezoids are shingled; the rectangle is not shingled. Find the area of one of the smaller trapezoids. A ¬1 2 h(b1 b2)

9.

10.

¬1 2 (16)(34 10)

¬352


12

b3 A ¬1 2 h(b3 b4) 1 ¬2(16)(69 45)

12

b2

45

580

¬912 Find the total area to be covered T 2(352) 2(912) 2528 The total area to be covered is 2528 ft2. The blue area consists of two rectangles, a circle, and two semicircles that combine to make another circle like the first. Area of rectangles: A 2(w) 2(19)(12) 456 Area of circle and semicircles: A 2( r2) 2 (62) 72 The total area is 456 72 or about 682.19 ft2. There are 8 black squares (including 4 in the corners) and 8 black triangles whose area is the same as 4 squares—a total of 12 black squares. The area of one square is 2 2 or 4 ft2, so the area of the black tiles is 12 4 or 48 ft2. The mosaic measures 5 2 or 10 feet on a side, so its area is 100 ft2. Using the information from Exercise 7, area of red tiles area of mosaic area of black tiles 100 48 or 52 The area of the red tiles is 52 ft2. The total for the black tiles is greater. For the red tiles, there are 4 hexagons (6 sides) and 5 squares (4 sides), so the red tiles have a perimeter of 2[4(4 2 2 ) 5 4] 72 16 2 feet. For the black tiles, there are 8 squares (4 sides) and 8 triangles (3 sides), for a perimeter of 2[8 4 8(2 2 )] 96 16 2 feet. Find the area of the blue region, using r1 12 and r2 12 10 22. A r22 r21 (222) (122) 340 Find the area of the target, using r 12 10 8 30. A r2 (302) 900

3. The wing loading factor is given by w s . For w 750 and s 532, the wing loading factor is 75 0 532 or about 1.41.

area of blue region

P(blue) ¬ area of target 340

¬ 900 17 ¬ 45 or about 0.378

4. The surface area of the inside of the pan equals the sum of the lateral area of the pan plus the area of its base. The lateral area of the pan is given by L Ph, where P is the perimeter of the pan and h is the height of the pan. The area of the rectangular base is given by B w, where is the length of the pan and w is its width. Calculate the surface area, T. T Ph w (2 9 2 13)(2) 13 9 205 The area of the inside of the pan that needs to be coated is 205 in2. 5. If a right cylinder has a lateral area of L units, a height of h units, and the bases have radii of r units, then the lateral surface area, the circumference of the bases times the height, is given by L 2 rh. Find the lateral area of the coaxial cable. First, convert 3 inches to feet. 1 ft 3 in. 12 in. 0.25 ft Now, calculate the lateral area. L ¬2 rh

The probability that the dart lands in the blue region is about 0.378. 11. Find the area of the sector containing the convention center. N 2 A 360 r 13 0 2 360 (1.5)

0.8125 Find the probability. area of sector P(near convention center) ¬ area of circle 0.81 25 ¬

(1.5)2

13 ¬ 36 or about 0.361

The probability of a visitor being housed in the 13 sector with the convention center is 36 or 36.1%.

Chapter 12 Surface Area Page 793

¬2 d 2h

1. Sketch the top, left, front, and right sides of the Eiffel Tower.

0.25 ¬2 2 (500)

¬392.7 The lateral area of the coaxial cable is about 392.7 ft2. 6.

top view

left view

front view

right view

3 cm

2. The roof is composed of eight identical right triangles. The length of one leg of each triangle is 34 2 or 17 ft. The other leg of each triangle is the hypotenuse of another right triangle. This right triangle is half of the triangular portion of the wall of the building with legs of lengths 30 ft and 17 ft. Use the Pythagorean Theorem to find the length of the other leg. c2 a2 b2 c2 302 172 c2 900 289 c ¬1189 c ¬34.48 Calculate the area of a single triangular portion of the roof.

7. A tetrahedron is a regular triangular pyramid. It has four congruent equilateral triangular faces, so the total area of the shaker is four times the area of one face. The height of the triangle can be found using the Pythagorean Theorem. c2 ¬a2 b2 2

32 ¬h2 3 2

9 ¬h2 2.25 6.75 ¬h 2.6 ¬h Calculate the area of a single face. A ¬1 2 bh 1 ¬2(3)6.75

A 1 2 bh 1 2(17)1189

¬3.9 The area of the shaker is 4 1 or about 2 (3)6.75 15.6 cm2.

293.096 The area of the entire roof is 8 1 or 2 (17)1189 about 2344.8 ft2.

581


8. The total surface area of the bin is the sum of the lateral areas of the cones and the lateral area of the cylinder. The lateral area of a cone is given by L r, where r is the radius of the base and is the slant height. The lateral area of a cylinder is given by L 2 rh, where r is the radius and h is the height. To find the surface area, we first must find the slant heights of the cones. The radius of the cone and its height are the legs of a right triangle and the slant height is the hypotenuse. Use the Pythagorean Theorem to find the slant height in terms of the height and diameter of a cone. 2 r2 h2

Chapter 13 Volume Page 794 1. If the diameter is 42, the radius is 21. Use the formula for the volume of a cylinder. V r2h (21)2(19) 26,323.4 The volume is approximately 26,323.4 in.3. 2. The spacecraft is a rectangular prism. 8 2 feet 8 inches equals 2 2 3 feet or 3 feet. 3 feet 8 11 inches equals 3 2 3 feet or 3 feet. V ¬Bh 1 1 ¬8 3 3 (4)

2

2 2 d 2 h 2 2 2 1 4d h

35 2 ¬ 9 ¬39.1 The volume is approximately 39.1 ft3. 3. The part that contains air is a hexagonal prism whose height varies. The perimeter of the base (a regular hexagon) is 6(6) or 36 inches. Find the area of the base.

1d2 h2 4

Find the total area T. T 2 rh rtop rbottom 1 2 1d2 h2top h2bott om 4 d 4 1 8 1 2 52 (18)(12) 2 4 (18)

dh d 2

18 2 2

2 1 4 (18) (28 5 12 2)

(216 9106 9162 ) (216 9106 812 ) 1330 The surface area of the bin is (216 9106 812 ) 1330 ft2. 60 3

9. The globe is a sphere. Find the surface area of a sphere of diameter 16 inches. T 4 r2 2

4 d 2

d2 (16)2 256 804.2 The surface area of the globe is about 804.2 in.2. 10. Earth is a sphere. Find the surface area of a sphere of diameter 7926 miles. T 4 r2 2 4 d 2 d2 (7926)2 197,359,487.5 The surface area of Earth is 197,359,487.5 mi2. 11. The ratio of the surface area of the globe to that of Earth is equal to the ratio of the surface area of Africa on the globe to that of Africa on the Earth. Let x be the surface area of Africa on the globe. Find x.

Area: A 1 2 Pa 1 ) 2 (36)(33

543 Now find the volume of air. Fully expanded: The bellows of the concertina is 36 2 2 32 inches tall. V Bh (543 )(32) 2993.0 Compressed: The bellows of the concertina is 7 2 2 3 inches tall. V Bh (543 )(3) 280.6 So, the volume of air in the concertina is 2993.0 in3 when fully expanded and 280.6 in3 when compressed. 4. Each cell has a radius of 1 2 (75) or 37.5 ft. Find the volume of one cell. V r2h (37.5)2(210) 295,312.5

256 x 11,70 0,000 ¬ 197,359 ,487.5 256 (11,700,000) x ¬ 197,359,487.5

x ¬47.7 About 47.7 in.2 will be used to represent Africa on the globe.


3

Apothem: In a 30°-60°-90° triangle, if the side opposite the 30° angle is x units long, the side opposite the 60° angle is x3 units long. Here the apothem of the hexagon measures 33 inches.

582

Multiply by 20 to find the volume of the storage cells. The volume is 20(295,312.5 ) or about 18,555,031.6 ft3.

9. If the scale factor is a to b, the ratio of the volumes is a3 to b3. Here the ratio is 13203 to 1 or 2,299,968,000 to 1. 1. 5 10. Solve the proportion, using 1.5 inches 12 or

5.

3 feet. 24 golfer height giant golfer height ¬ golf ball diameter Spaceship Earth diameter x 6 ¬ 165 3

h 16

24

7.25

6 165 ¬x 3

24

14.5

Use the Pythagorean Theorem to find the height. a2 b2 ¬c2 (7.25)2 h2 ¬162 52.5625 h2 ¬256 h2 ¬203.4375 h ¬14.263 Now find the volume.

7920 ¬x The golfer would need to be 7920 ft tall. 11. ST (x2 x1)2 (y2 y1)2 (z2 z1)2 2 ( [3 (10)] 2 ( 8 5) 1 3)2

354 TR (x2 x1)2 (y2 y1)2 (z2 z1)2

V 1 3 Bh 1 3(14.5)2(14.263)

2 [ (7 3)2 [4 (8)] 2 ( 1)]2

117 or 313

1000 The volume is approximately 1000 cm3.

SR (x2 x1)2 (y2 y1)2 (z2 z1)2 [7 (10 )]2 ( 4 5)2 (2 3)2

6. The radius of the sphere is 1 2 (165) or 82.5 feet. 4 3 V 3 r

115 So ST 354 feet, TR 313 feet, and SR 115 feet.

3 4 3 (82.5)

12. Let O (0, 0, 0).

2,352,071 The volume is approximately 2,352,071 ft3. 7. The radius of the sphere is 1 2 (1.5) or 0.75 in.

OS (x2 x1)2 (y2 y1)2 (z2 z1)2 (10 0)2 (5 0)2 (3 0)2 134

3 V 4 3 r 3 4 3 (0.75)

OT (x2 x1)2 (y2 y1)2 (z2 z1)2 2 ( (3 0) 8 0)2 ( 1 0)2

1.8 The volume is approximately 1.8 in3. 8. Write the ratio of the corresponding measures of the spheres. 165 feet equals 12(165) or 1980 inches.

74 OR (x2 x1)2 (y2 y1)2 (z2 z1)2 (7 0)2 (4 0)2 (2 0)2 69 The star located at S is farthest from the center of the room.

diameter of the larger sphere 198 0 1.5 diameter of the smaller sphere 13 20 1

The scale factor is 1320 to 1.

583


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